girls and a level physics : identity and choicesshura.shu.ac.uk/17710/1/31296_thorley.pdf ·...
Post on 11-Oct-2020
1 Views
Preview:
TRANSCRIPT
Girls and A level physics : identity and choices
THORLEY, Amelia Deborah Maud
Available from Sheffield Hallam University Research Archive (SHURA) at:
http://shura.shu.ac.uk/17710/
This document is the author deposited version. You are advised to consult the publisher's version if you wish to cite from it.
Published version
THORLEY, Amelia Deborah Maud (2014). Girls and A level physics : identity and choices. Doctoral, Sheffield Hallam University.
Copyright and re-use policy
See http://shura.shu.ac.uk/information.html
Sheffield Hallam University Research Archivehttp://shura.shu.ac.uk
Sheffield Hallam UniversityLearning and fo rm a tio n Services
Adsetts Centre. City Campus Sheffield 3 ‘i 1VVD
' I ZOI S
1 0 2 0 5 6 9 0 3 4
Sheffield Hallam University Learning and information Services
Adsetts Centre, City Campus Sheffield S1 1WD
REFERENCE
Girls and A level Physics: Identity and Choices
Amelia Deborah Maud Thorley
A thesis submitted in partial fulfilment of the requirements of Sheffield Hallam University
for the degree of Doctor o f Philosophy
July 2014
Abstract
This thesis addresses the question o f how physics identity and physics self efficacy influence girls’ choices to study or not to study physics post-16. This question is important because only 20% of the overall 16-18 physics cohort in England and Wales is female.
A theoretical framework for physics identity is proposed using socio-cultural theories. An extensive review o f the current literature on the issue o f girls in physics, physics identity and physics self efficacy was used to support this framework.
A mixed methods methodology with a funnelling approach to selecting participants was used. Two schools were selected because they had in the past demonstrated a higher than average progression rate for girls onto post-16 physics. An initial questionnaire was completed by 458 14 and 15 year old pupils. From the answers given on the questionnaire, 43 girls were selected to participate in three rounds o f small group interviews. These girls were ones who were both thinking o f studying physics post-16 and those who were not. Finally, extended narratives o f four girls were developed to illustrate the links between physics identity, physics self efficacy and physics choice.
Descriptive analysis of the questionnaire data was used to give a background picture o f the pupils’ overall views about science and physics, science and physics teachers and lessons and how they felt about physics. The group interview data was analysed thematically drawing on the themes identified in the literature review and themes that emerged from the data. The stories o f four girls were analysed using narrative methodology.
The results show that the issues of girls’ engagement in physics cannot be resolved unless a holistic view is taken; that developing identification with physics occurs within the wider identity development of the girls that takes place in the many figured worlds that they inhabit. Particular notice needs to be taken of how girls’ identification with physics develops due to interactions with teachers; how physics plays a part in the discourse o f achievement and how society in general influences this identification. The research showed that there was little difference between future choosers and non choosers o f physics.
b
Acknowledgements
I would like to take this opportunity o f expressing my thanks to all those people
who have helped me in any way to complete this thesis.
Firstly I would like to thank the management and teaching staff o f the two
schools who agreed to support my work by allowing me to interview their
students. A massive thank you to the girls from both schools who came to talk to
me and shared their experiences of physics with me. Without them, there would
not be a thesis.
My sincere thanks to Prof. Hilary Povey and Dr Mark Boylan for then-
productive comments throughout the time I have been working on this project
and their constructive feedback on the writing o f the thesis. My thanks also to all
the other staff and researchers at the University who have made helpful
comments throughout this period.
Finally I would like to thank my family and friends for all their support. To those
who have read through earlier drafts to the thesis and commented on it; to those
who have let me talk to them when I have had a problem; and especially to my
extended family at St James who have given my much needed spiritual support
throughout the whole research process.
c
Index
Chapter 1 Introduction p i
Science Education in England p2
Participation in A-level Physics p3
Researching Identity, Self Efficacy and Girls’ Physics Choices p7
Introducing My Position as a Researcher p9
The Thesis Outlined p i 1
Chapter 2 Girls and Physics p i3
Introduction p i 3
Gender and Science - a Historical View p i4
Recent Reviews o f the Literature on Girls in Science and Physics p i 6
General Attitudes to Science and Physics p21
Choices p26
Choices linked to future careers p28
Influences o f Teachers and Teaching p30
Influences o f Others p36
The Image o f Physics p37
Conclusion p43
Chapter 3 A Developing Framework for Identity and Self Efficacy p46
Introduction p46
Developing a Framework for Identity p47
What is identity? p47
Communities o f Practice p50
Communities o f practice in science education literature p51
Criticisms o f communities o f practice theory p55
Figured Worlds p57
Figured worlds in science education literature p58
Communities o f Practice or Figured Worlds? p66
Self Efficacy p68
Studies of self efficacy p70
Identity, Self Efficacy and Narrative p72
i
Summary p76
Chapter 4 Methodology and Method p78
Introduction p78
Methodological Approach p78
Pilot Research p81
Case Study Methodology p82
School Selection p85
Questionnaire p87
Lesson Observations p91
Interviews p92
Active interviewing p92
Interview sampling and conduct p94
Interview data processing p95
Interview analysis p98
Developing Narratives p99
Ethical Issues p i 04
Chapter 5 The Schools and The Questionnaire Results p l07
Introduction pl07
The Schools pl07
Browning School p l07
Lesson observations p i 10
Hinton School p i 12
The Questionnaire Data p i 16
Possible A-level choices p i 17
Why choose or not choose physics? pl21
Physics words p i 24
How do I compare myself to others? pl27
Teachers and interest in science or physics p l30
Science and physics lessons pl34
Discussion p 141
Chapter 6 Do Only Polish Women Choose Physics? p i45
ii
Introduction p i 45
Introducing the Interviewees p i46
Browning School p i47
Year 9 pl47
Year 10 pl50
Hinton School p i 52
Year 9 p i 52
Year 10 p 155
Summarising the interview groups p i 57
Interview Themes and Process p i 59
Exploring Reasons for A-level Physics Choices p i 59
Influences p i 61
F amily influence s p 161
Peer influences p i 64
Teacher influences p i 66
Influence o f society p i 72
Self efficacy p i 80
Previous performance p 181
Comparison to similar others p 181
Feedback p i 83
Physiological factors p 185
Self efficacy and A-level physics choices p 186
A discourse of achievement p i 87
Discussing the Multiple Influences p 191
Chapter 7 Narratives o f Identification with Physics p i 94
Introduction p i 94
Interview processes and analysis p 195
Rose p i 97
Indiana p207
Charlotte p214
Scout p219
Discussion p227
The four narratives p228
iii
Relating the narratives to the literature p229
Chapter 8 Conclusion p235
Introduction p235
Research Outcomes p236
Making choices p237
Teacher - student interactions p23 8
Recommendations and implications p241
The discourse o f achievement p242
Recommendations and implications p243
Similarity and differences between physics choosers and non
choosers p244
Recommendations and implications p246
Complexity and interrelationships o f figured worlds p247
Recommendations and implications p249
Researching Girls and Physics p249
Methodological processes p250
Theoretical frameworks p251
Limitations o f the research p254
Future directions and further research p256
The Contribution o f the Study p258
Concluding Remarks p259
References p262
Appendices p278
List of Tables and Figures
Chart 1-1 - A-level Physics Entries 2000-2011 p4
Chart 1-2 - AS level Physics Entries 2001-2011 p5
Figure 3-1 Configuring identity trajectories p63
Figure 3-2 Representations of four of the many possible science identity
trajectories a hypothetical latecomer to science may construct during her
first year in CEGEP science p65
Table 5-1 Reported ethnicity o f pupils in survey sample p 109
Table 5-2 Reported socioeconomic background o f parents/guardians of pupils in
survey sample p i 09
Table 5-3 AS Physics gender breakdown pi 13
Table 5-4 A2 Physics gender breakdown p i 13
Table 5-5 Reported ethnicity o f pupils in survey sample p i 14
Table 5-6 Reported socioeconomic background of parents/guardians of pupils in
survey sample p 115
Table 5-7 Pupils who answered survey p i 16
Chart 5-1 Browning Year 9 A-level choices p i 18
Chart 5-2 Browning Year 10 A-level choices p i 18
Chart 5-3 Hinton Year 9 A-level choices p i 19
Chart 5-4 Hinton Year 10 A-level choices p i20
Table 5-8 Reasons for Thinking o f Choosing A-level Physics p i 22
Table 5-9 Reasons for Not Thinking o f Choosing A-level Physics pl23
Chart 5-5 Girls who are thinking o f choosing A-level physics p i 25
Chart 5-6 Boys who are thinking o f choosing A-level physics p i 25
Chart 5-7 Girls who are not thinking o f choosing A-level physics p i 26
Chart 5-8 Boys who are not thinking of choosing A-level physics p i 27
Table 5-10 Comparing my physics ability to the rest o f my class p i 28
Table 5-11 Comparing how much I like physics to my friends p i29
Table 5-12 Comparing my results to Bennett and Hogarth p 131
Table 5-13 Do my teachers make me more interested in science or physics?
p 133
Table 5-14 Browning School year 9 p i 35
v
Table 5-15 Browning School year 10 p 136
Table 5-16 Hinton School year 9 p i37
Table 5-17 Hinton School year 10 p 13 8
Table 8-1 Comparing Blickenstaff with Murphy and Whitelegg p251
vi
Chapter 1 Introduction
The number o f students studying physics post compulsory education is
recognised by the government and those working in industries that employ
STEM (science, technology, engineering and mathematics) graduates as being
too small to meet the future demand for physicists. The UK government (DIUS,
2009) has asserted that to continue as a wealthy nation there needs to be an
increase in the number o f STEM qualified entrants into the workforce. The
proportion o f students taking AS and A-level1 physics who are female has
remained at about 20% for a number o f years. Increasing the number o f girls
taking physics could be one way of increasing the overall number.
The issue o f why more girls do not study physics and other physical sciences,
including engineering, has formed part o f the ‘women in science’ debate for
many years. This issue has been the concern not only o f the policy makers
mentioned above but o f those working in the STEM sector, teachers and
activists. Initiatives started to appear from the 1970s onwards (Phipps, 2008)
when, in the UK, acts to ban discrimination and to give equal pay started to be
introduced in the workplace. These initiatives included classroom based action
research interventions, after school and residential courses for pupils, support and
networking for female STEM students and professionals and training
programmes for socially excluded women (Phipps, 2008). Even after these many
years o f initiatives, women are still under represented in the STEM workforce,
especially the physical sciences. There is still a need to investigate why equality
has not yet been achieved or, as is the case with A-level physics entries, why the
proportion o f girls taking the subject has not changed.
In this first chapter, I outline the key issues and give an overview o f the structure
o f the thesis as a whole.
1 For explanation of these terms, see next section on science education in England.
1
Science Education in England
Science is taught in English and Welsh schools as part o f the National
Curriculum. Schools in England and Wales follow a similar National
Curriculum, similar examinations and have a similar schooling system, although
there are some anomalies in Wales. The schooling system in Scotland and
Northern Island, the other two countries that form the United Kingdom at the
time o f writing, have their own schooling system, curriculum and examination
systems. This introduction to science education is therefore a description o f the
English system alone.
Education in England is compulsory and free at state schools for all children
from the age o f five until 16 (which rose to 17 in 2013) and all young people
have to remain in some form o f education or training up to the age o f 18. School
years are numbered with children starting school in year 1 and taking their
GCSEs in year 11. The majority o f children start their secondary education at age
11 but in some areas o f the country they do not start it until age 13. The majority
of secondary education takes place in schools that cater for 11-16 year olds or
11-18 year olds. At the age o f 16 the majority o f children2 take General
Certificate o f Secondary Education (GCSE) examinations. These are in the core
subjects o f English, mathematics and science as well as other subjects chosen by
the individual student.
The majority o f secondary schools in England are non selective, comprehensive,
mixed sex schools. The intake to these schools varies depending on the location
o f the school and the socioeconomic nature o f the population in that location.
There are a small number o f fully selective schools where students must pass an
examination to gain entry. There are four main types o f state schools in England.
These are community schools which are funded by the local council; foundation
schools which have more freedom to deliver their own curriculum than
community schools; academies which are publicly funded independent schools
and can deliver their own curriculum; and selective grammar schools. A small
2 Some children with special educational needs do not take GCSE examinations.
2
number o f Free schools have been established recently that are funded by central
government and do not have to follow the national curriculum.
The majority o f schools teach following the national curriculum. Students must
study science as part o f this curriculum. When they take their GCSE
examinations, they can take two GCSEs in science where they study a
combination o f biology, chemistry and physics or three GCSEs, one in each o f
the separate sciences. Schools are encouraged to enter those students who have
higher attainment for the three separate science subjects. GCSEs are graded from
A* (the highest grade) to G. Grades A* to C are considered to be the best grades.
Once students have completed their GCSEs there are a number o f options for
further, post 16, study. One o f these is to take Advanced Level (A-level)
qualifications at the age o f 18. In the first year o f post 16 study, students who are
following an A-level programme will take Advanced subsidiary (AS)
examinations. They can then continue to study the subject for the full A-level,
taking this examination after another one year o f study. Students usually study
three or four subjects at A-level. In England, A-levels are regarded as the$
standard entry requirements for many university courses. A-levels are grades A
(the highest grade) to E with all grades considered as pass grades.
Participation in A-level Physics
Since the introduction o f Curriculum 2000 (DFEE, 1997) in 2000, the last major
change in A-levels, the numbers studying A-level physics dropped to 23657 in
2006 from 28191 in 2000 but has then risen to 29206 in 2011. During the same
time the number o f girls studying A-level physics has dropped from 6396 in
2000 to 4970 in 2006 and back up to 6013 in 2011. The percentage o f girls
studying A-level physics as a proportion o f the overall entries has remained
constant at about 20 % (see chart 1-1 below, based on DfE, 2012).
3
A-level physics entries
35000
30000
25000
20000a>£3
15000
O T otal□ Male
□ Female
10000 --
5o°o a — 1 — ■ — — In — g-t - | —|— —|— I - ]— I — ■ — I
2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011
Year
Chart 1-1 - A-level Physics Entries 2000-2011
Curriculum 2000 introduced a split from the traditional two year A-level into a
1+1 A-level where an AS qualification is taken in the first year and then a full A-
level, via an A2 examination, in the second year. This has allowed students to
take a wider range of subjects in their AS year. The numbers studying for AS
level physics are therefore higher than those taking the full A-level. In 2011 there
were 49079 entries for AS level physics from 37689 boys and 11390 girls (see
chart 1-2, based on DfE, 2012).
4
AS Level Physics Entries
60000
50000
E 30000
10000 - -
o I: ■ I I 1-.M I l- M , I-.M I I I I ■ I I I. ■ 1 , 1 ■ 1 , 1 ■ 1 , 1 ■ I , L...M2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011
Year
□ Total□ Male
□ Female
Chart 1-2 - AS level Physics Entries 2001-2011
A more detailed interrogation of the 2011 data from the National Pupil Database
(a database held by the Department for Education recording all school pupils)
was carried out by the Institute o f Physics (2012). This investigation not only
looked at the numbers of students entered for A-level physics in 2011 but also
patterns in progression data from GCSE to A-level. Girls and boys achieve
equally well in GCSE science or physics so there should be no difference in
progression based on prior achievement. However they found:
• that 46% of all schools did not send any girls onto A-level physics
compared with 14% for boys
• that independent and single sex schools were more likely to send girls
onto A-level physics
• that students are less likely to progress to A-level physics from 11-16
schools than from 11-18 schools
• that the overall academic achievement of a school affects the percentage
o f girls progressing to A-level physics with the higher the achievement
the higher the progression
• that socioeconomic background affects progression for all students.
5
The Institute o f Physics followed this report up with one looking at the gender
balance in schools with respect to six ‘gendered’ subjects (IOP, 2013). They
found that four out o f five state-funded co-educational schools did no better than
the national gender ratios for progression onto these A-level subjects (which
were English, mathematics, biology, physics, psychology and economics). The
majority o f schools were, therefore, maintaining the gender stereotypes o f these
subjects.
Boaler, Altendorf and Kent (2011) have also recently investigated performance
and participation patterns in mathematics and science in the United Kingdom.
They found that girls who do take A-level physics get a slightly higher
proportion o f the highest grades A*-C than boys. They also found that only 13%
of girls who gain an A* (the highest possible grade) at GCSE progress onto A-
level physics compared with 64% o f boys. Therefore, attainment is not a barrier
to progression.
These two recent reports do not give answers to the problem, just highlight that
there are still differences that need to be investigated further. The concern about
the small percentage o f girls who take A-level physics, and the low progression
rate o f high achieving GCSE girls compared with boys, led to the Institute o f
Physics publishing two booklets looking at the question o f ‘Girls in Physics’ in
2006. One o f these was a review o f literature by Murphy and Whitelegg,
discussed in detail in Chapter 2, and the other was a handbook o f suggestions for
teachers. Murphy and Whitelegg’s review o f the literature showed there was a
gap in the literature about ‘girls’ experiences o f science and physics in schools in
England and how this informs their attitudes and future aspirations’ (Murphy and
Whitelegg, 2006a, pvi). One o f the responses following the publication o f these
booklets was an action research project where physics teachers carried out small,
in-school projects to look at strategies for increasing the participation o f girls
with physics in their schools (Institute o f Physics, 2010). Strategies suggested in
this work included the use o f role models, one day physics-related careers
workshops and using a ‘girl friendly’ checklist for classroom activities.
6
Two major research projects, both funded by the Economic and Social Research
Council, the UPMAP project (Understating Participation rates in post-16
Mathematics And Physics) and the ASPIRES project (focusing on primary age
children) have looked at the issue o f low participation in science subjects in
England recently. Both projects used a combination o f a large quantitative survey
followed by qualitative interviews to research the issue. The ASPIRES project
used an on line survey (Archer et al., 2013) completed by 9319 students aged 10
or 11 and interviews with 78 parents and 92 students. The students who
completed the questionnaire will be re-surveyed at a later date. The interviews
were single visit interviews. The UPMAP project intends to interview 70
students aged 15 and then re-interview them at age 16 and 17 (UPMAP, 2008).
Even though there has been a great deal o f research about why girls still do not
study physics (and to some extent the other sciences) in higher numbers post-16,
there are still areas to investigate with regard to this question. One area that has
not been studied in depth is how identification with physics influences choice.
This is the area that this study focuses on.
Researching Identity, Self Efficacy and Girls ’ Physics
Choices
This thesis contributes to this developing body o f knowledge by examining why
girls choose or do not choose to study physics for A-level through a focus on
physics identity and physics self efficacy. The aims o f the research were to:
1. interrogate the current literature on identity and self efficacy to develop
definitions o f physics identity and physics self efficacy and then to
develop a theoretical model linking the two
2. explore what physics identity and physics self efficacy meant for girls in
school years 9-11 and produce narratives to examine how these impact on
future subject choices.
7
I proposed a theoretical framework for physics identity using the theories of
Jenkins (2009) and Gee (2001) which was developed in figured worlds (Holland
et al., 1998). Although there is a growing body of literature using figured worlds
to describe science identities, this has not been in the area o f physics identities
nor in England. I also argue that physics self efficacy forms a part o f physics
identity and these two phenomena have not been linked in such a direct way
before. Much work investigating choice in the past has been done quantitatively.
Investigating choice as part o f identity work and using a narrative approach
(telling individual stories o f girls’ identification with physics and how this
impacts on their choices) is a new area to which this work contributes.
A pilot study completed for my Masters thesis (Thorley, 2010) which
investigated why girls had chosen to study A-level physics, gathered data from
girls who had completed the first year o f their A-level programme. These girls
had chosen physics both for interest and to support future career goals. The
findings from this study were used to inform the present study but were excluded
from the current data set.
Previous research on identity and self efficacy has been carried out,
independently, in two different disciplines and using a wide range o f different
theoretical frameworks. The result o f this is confusion about what the terms
‘physics identity’ and ‘physics self efficacy’ actually describe. The research
presented here contributes to the development o f a theoretical model linking
physics identity and physics self efficacy. It was developed by considering the
choices, identity and self efficacy o f girls at two schools in England. The
proposed model was refined and used to examine the impact on future subject
choices.
This research used a mixed method approach. Two schools were identified where
they had a higher than average (20%) percentage of girls in their A-level physics
classes; these were atypical schools in that they had a high proportion o f students
from a White, high socioeconomic grouping background. An initial questionnaire
was given to all year 9 and 10 pupils at the two schools. Using these
questionnaires, 43 girls, including both those who had expressed a possibility o f
8
choosing A-level physics in the future and those who had not, were selected to
participate in three rounds o f small group interviews. These interviews
investigated the reasons for those future subject choices, the factors that
influenced them, and aspects o f identity and self efficacy linked to physics.
Finally, narratives for four girls were developed to illustrate how physics identity
and physics self efficacy impacted on their choice not to study physics for A-
level.
Introducing My Position as a Researcher
Given both the qualitative nature of the methodology used in this research and
the focus on identity and self efficacy, it is important to introduce myself. I form
an important part o f this research. You cannot participate in qualitative research
without part o f yourself influencing the decisions you make methodologically.
My background affected how I interacted with the girls I interviewed and how I
produced their narratives. Knowing a little about me will help the reader to place
this research in context.
My name is Deborah and I am a .. .If I make a list of who I think I am this list
would look like : I am a woman, I am a sister, I am an aunt, I am a chemist, I am
a teacher, I am a bellringer, I am a family historian and a few more. At the
beginning o f this research nowhere on that list would be ‘I am a social scientist’.
As I am nearing the end o f this research I still do not feel that I am a social
scientist but I would say that I am beginning to understand what one is and that I
am starting to think like one some o f the time.
I made the decision that I wanted to be a scientist at about the age o f fourteen
when I was choosing my Ordinary Level (O-levels) . I knew then that if I wanted
to become a scientist I would need to study all three sciences for O-level, even if
my headteacher felt that this would make me a one dimensional person and tried
to encourage me to only study two o f them and choose another humanities
3 O-levels were the precursors to GCSE.
9
subject instead. But I was adamant; I wanted to be a scientist and therefore I
needed to study all three sciences. This did prove to be the case when I started
looking for university courses and the number you could apply for was greatly
reduced if you did not have all three sciences for O-level. At this time I was
thinking o f biochemistry, but eventually I studied chemistry and really enjoyed
that.
I cannot really remember what made me so interested in science, but I have
always liked facts. I like being able to give the correct answer to a question. I can
define water as being two atoms o f hydrogen linked to one o f oxygen to give the
molecule water. I know that there are many aspects about the properties o f water
that are still unknown, but a molecule o f water is always the same. One o f my
issues with the humanities and social science has always been that you can
discuss things and interpret your answers. I read a book and enjoy it, but don’t
want to discuss why the author wrote it in a certain way or what you can deduce
from how they described a character. This was my biggest issue when
researching identity and self efficacy for this thesis. There is not one definition.
Identity and self efficacy can be described in many different ways. One o f the
aims, therefore, o f this research was to develop a definition o f physics identity
and physics self efficacy that would help me, and others (especially physics
teachers), to explain how these factors influence girls (and boys) when they are
making their choices about what subjects to study post 16.
Paradigmatically speaking I have worked in a positivistic way for many years.
As a teacher, I moved towards post positivism as a way to understand the
involvement o f the individual in learning. Changing my world view to
encompass more o f how individuals construct their meaning o f the world has
been, and still is, a painful journey at times. Further discussion on these issues
can be found in Chapter 4.
10
I
The Thesis Outlined
Chapter 2 o f the thesis gives an overview of some o f the current literature on
girls and physics. It starts with an historical view of ‘the problem’ o f girls in
science then continues by looking at three recent reviews on the issues. Using
these reviews as a starting point, I then look at the different themes that have
been used to investigate the relationship between girls and physics (and science
and mathematics where relevant). I use five themes and propose that these are a
good framework for fixture reviews o f the literature.
In Chapter 3 I develop a description o f physics identity based on the work o f
Jenkins (2009) and Gee (2001) and which is developed within figured worlds
(Holland et al., 1998). I then interrogate how identity has been used by others to
describe science and physics identities. In this Chapter I also interrogate the
literature about self efficacy to show one way in which identity and self efficacy
can be linked. This results in a theoretical framework that I use in the analysis o f
my data.
In Chapter 4 1 describe the methodological journey taken during the project. The
project started life as a two school case study. The methods included in the case
study were a questionnaire to gather background data about pupils in year 9 and
10, small group interviews with girls who were both thinking o f and not thinking
o f choosing physics for A-level, lesson observations and investigating supporting
documentation for the schools. As the research developed, the emphasis changed
to using the small group interviews as the main data gathering tool. Following
thematic analysis o f the interview data, a final methodological change was made
to using narratives. Throughout the discussion o f methods, I interweave a
discussion o f my methodological thinking.
The schools chosen as research centres are described in Chapter 5. In this
Chapter I also present the findings from descriptive analysis o f the questionnaire
data. Data for both girls and boys is discussed and compared for similar and
different trends. Similarities and differences in the data for those pupils who
11
were thinking o f choosing physics and who were not thinking o f choosing
physics is also compared. Comparison o f the data to similar data sets is also
described here.
I introduce the girls chosen for the group interviews in Chapter 6, explaining the
reasons for my choices. The group interview data is analysed using both
deductive and inductive themes. These themes are explored and quotes used to
illustrate the points made. New contributions to the debate on why girls choose
or do not choose to study physics post 16 further are identified and discussed.
The findings show that girls’ choices are impacted by teacher - student
interactions with special regard to physics confidence, by the discourse o f
achievement and by the complexity and interrelationships within figured worlds.
The findings also show that there are many similarities as well as differences
between both physics choosers and physics non choosers.
Chapter 7 presents the narratives o f four girls. I used a narrative approach to
analyse their stories and so present them in this way. These narratives illustrate
that many factors influence a girl’s identification with physics (including her
physics self efficacy) and her possible future choice as to whether to study the
subject post-16 or not. For some girls there are significant points in time that can
be identified as having a major impact on her identification with physics and that
can change her physics identity trajectory. For others, it is a combination o f
factors that either push her away or pull her towards physics. For each girl, the
importance o f the different influencing factors, and the amount o f push or pull
they have, is different. It is the overall combination o f these influencing factors
that impacts on her identification with physics and her ultimate choice as to
whether to study it further or not.
Chapter 8 concludes the thesis. I present a summarising discussion o f how
physics identity and physics self efficacy and the factors that influence them can
be used to understand subject choices. For each o f the knowledge claims I
discuss the implications and make recommendations for action. I finish by
discussing the limitations o f my research and make suggestions for future
studies.
12
Chapter 2 Girls and Physics
Introduction
In this chapter I discuss previous research literature about girls and physics. I
start the chapter by putting the issue into its historical context by giving an
overview of the history o f the gender and science argument. I continue the
chapter by looking in more detail at the recent reviews written by Blickenstaff
(2005), Brotman and Moore (2008) and Murphy and Whitelegg (2006a) before
adding to these discussions with a review o f the more recent literature.
My review o f the literature starts by looking at how general attitudes to science
and physics can influence students’ choices as to whether to pursue a study of
these subjects past compulsory education; I then move on to look at the choice
literature in more detail. Separating out the attitudes literature from the choice
literature can be problematic at times since there is overlap between the two
bodies o f literature, but this differentiation seemed appropriate for this thesis
since it focuses on choice rather than attitudes.
I begin by looking at choices in general, focusing on science subject choices,
before moving on to look at how choices are linked to future careers. I then move
on to look at how teachers and teaching and significant others can influence
future subject choice. I close with looking at the image o f physics as an
influencer o f choice. This section looks at how stereotypical views o f physics as
being a hard subject, a masculine subject and primarily for White, middle class
males can influence choice.
13
Gender and Science - a Historical View
In his recent book (2011), written to encourage more girls to study physics, ‘Fizz
nothing is as it seems’, Zvi Schreiber takes his eponymous heroine on a trip
through time to meet the giants o f physics. Of the 116 people she either meets
directly or discusses, only three (Marie Curie, Fabiola Gianotti and Caroline
Herschel) are women. This illustrates how few famous women physicists there
are and how long this problem has existed.
It was in the 19 century that the foundations were laid for the studying o f
science that we have today. Until that time, the study o f science had been
predominately a hobby for men o f independent means. Any women who did
participate, for example Caroline Hershel4, did so because o f the support o f their
family (in her case her brother). During the 19th century access to an education
became more widespread with even the poorest children becoming entitled to a
basic level o f education. The studying o f science became more important as the
Industrial Revolution grew.
fL
19 century science focused on the notions o f certainty, measurement and
control. Science was characterised by positivist thinking that empirical
experimental research yielded quantified and quantifiable data. Science was seen
as objective. Objectiveness was seen to be a male characteristic and so science
was not open to women who were deemed unable to be rational and objective.
This differentiating o f the sexes also developed during the 19 century and was,
as McAteer (2000) describes, in part due to the work o f Darwin. Darwin
published his On the Origin o f Species in 1859 which described the theory o f
natural selection. In 1871 he published The Descent o f Man which applies natural
selection to human beings. This work was used to justify the imbalances o f
power between individuals, races and nations by saying that some were more fit
to survive than others. These biological causes o f human behaviour could be
used to explain differences between the sexes. Based on their differing anatomy,
4 Caroline Hershel was a German-British astronomer who discovered several comets.
14
men and women were described as being not equal but complementary opposites.
This allowed for the division o f roles and labour based on sexual differences.
Therefore women could not participate in activities deemed suitable for men, for
example, science, due to their sex.
McAteer goes on to argue that the school science curriculum was, and still is,
influenced by universities. Universities see school education as a preparation fort l istudying at their institutions. University science in the 19 century became
dominated by experimental, laboratory based science. Therefore the early school
science curriculum could be termed to be a scaled down version o f this. This
version o f science was seen to be most suited to ‘able’ students who in the 19th
century were white, upper and middle class males. This became the stereotype
for a typical science student (see later section for more discussion about
stereotypes in science). The science that was offered to girls was that which was
deemed suitable for their development into good wives and mothers; namely,
domestic science.
thAs the 20 century progressed, school science continued to be seen as a
preparation for further university level study. Girls did enter scientific
professions, but many o f these professions were closed to married women sotVichoices had to be made. In the early and middle 20 century school science still
operated within a gender divide. Biology was seen as a girls’ subject and physics
as a boys’ subject. Many girls did not have access to physics teaching5.
Progress was made with the introduction o f the National Curriculum in 1988
which made the study o f science until age 16 compulsory. Until then choices
were made at age 14 as to what subjects to study. The number o f girls who chose
to study physics was still low during the 1970s and 80s so schemes started to be
put in place to encourage more girls to study science (e.g. GIST (Girls into
Science and Technology) and WISE (Women into Science and Engineering); see
Phipps, 2008 for a review o f UK initiatives).
5 My mother had to go to the local boys’ grammar school to study physics in the 1940s as her girls’ grammar school did not have a physics mistress and boys came to her school to study biology.
15
Research, which started in the 1970s and 1980s, on the girls and science
‘problem’ focused mainly on two issues o f science provision; that o f the
differential involvement o f girls and boys in science and that o f the differential
achievement o f girls and boys in science (Bennett, 2003). Research on the
differential involvement o f girls and boys in science also looked at their attitudes
to science as gender was seen to be a determining factor o f attitude. These areas
were focused on because in a time o f equal opportunities there was a need to
investigate the factors that impeded girls’ achievement in science; and because it
was conjectured that girls were avoiding science due to its perceived male nature
(see reviews o f Kaminski, 1982 and Manthorpe, 1982).
Further reviews in the 1990s (for example: Acker and Oatley, 1993; Catsambis,
1995 and Kenway and Gough, 1998) continued to look at the issue o f under
representation o f girls in science, in both education and the workplace. As
Kenway and Gough argued, ‘the notion o f enhancing girls’ post school options
should also encompass the wider economic, social, cultural and environmental
conditions in which they live their lives’ (p24) not just focus on short term fixes.
In the next section I look at three more recent reviews about ‘girls and science’
and ‘girls and physics’. These show that many o f the same issues identified in
earlier work are still o f concern to science educators but also that there is
beginning to be an emphasis on identity and self efficacy (see Chapter 3 for a
more in depth discussion o f these two areas).
Recent Reviews of the Literature on Girls in Science and
Physics
The three reviews discussed in this section are those o f Blickenstaff (2005),
Brotman and Moore (2008) and Murphy and Whitelegg (2006a).
Blickenstaff (2005) reviewed the literature looking at the absence o f women as
STEM majors in the US looking at whether they were leaking from the
16
‘pipeline’6 naturally or whether these leaks were some form o f gender filter.
Blickenstaff identified nine explanations that had been put forward in the various
STEM education research literatures to explain why women do not study or work
as scientists. These were:
1. biological differences between men and women
2. girls’ lack o f academic preparation for a science major/career
3. girls’ poor attitude toward science and lack o f positive experiences with
science in childhood
4. the absence o f female scientists/engineers as role models
5. science curricula are irrelevant to many girls
6. the pedagogy o f science classes favours male students
7. a ‘chilly climate’ exists for girls/women in science classes
8. cultural pressure on girls/women to conform to traditional gender roles
9. an inherent masculine worldview in scientific epistemology.
(p371-372)
As Blickenstaff says, many o f these nine explanations interact so intimately that
each alone cannot be used to explain the shortage o f women in STEM. After
looking at the literature, Blickenstaff rejected biological factors as an
explanation, because o f the lack o f evidence to support differences in ability, and
also academic achievement, because even girls who out performed boys dropped
out o f STEM subjects. Girls’ attitudes were found to differ from those o f boys
and that could be due in part to the lack o f role models, the design o f curricula
that favour, what are suggested to be, boys’ preferred ways o f learning and
teaching methods that devalue the contributions o f girls. The final three
explanations focus on social and cultural factors that support the generalised
view that science is for White, middle class males. Blickenstaff concludes that
the issue o f ‘girls and science’ is a complex one that requires a multi-faceted
solution.
6 Pipeline - the term used to describe the movement of girls through science education and onto a science career. The term, as used here, implies that the girls are perceived as a resource for the STEM industry.
17
Brotman and Moore studied research published between 1995 and 2006 in five
major peer reviewed science education journals and two other respected journals
that publish on a range o f issues including girls and science7. They reviewed 107
studies from around the world that dealt with pre-college education. The research
in these 107 studies looked at issues that related to girls or gender and science.
Research that was not included in the review was articles that focused on the
effectiveness o f single-sex education or where girls or gender and science were
not a primary focus o f the research. Reviewing these 107 articles for their
purpose, participants and setting, methodology and major findings lead to
Brotman and Moore grouping the research into four themes that reflected the
current trends in science education generally. These were:-
1. a focus on equity and access
2. a focus on curriculum and pedagogy
3. a focus on reconstructing the nature and culture o f science
4. a focus on identity.
They found that the order o f these themes also revealed a trend in the movement
of the focus o f research on girls or gender and science education over time with
the number o f papers on the first themes diminishing whilst those on the final
theme becoming more prevalent since entering the science research arena in
1995.
The first theme covered research looking at both the inequalities faced by girls in
science and work done to provide equitable science opportunities. They looked at
the differential treatment o f girls in science classrooms, the gender bias in
textbooks and how these contribute to different levels o f participation,
achievement and attitudes towards science o f girls and boys. Intervention
programmes where girls were given access to out-of school science experiences
and female role models as well as teacher education measures were also
discussed.
7 The journals were Journal of Research in Science Teaching, Science Education, International Journal of Science Education, Research in Science Education, Journal of Science Teacher Education, American Educational Research Journal and Gender and Education
18
The literature grouped in theme two described the argument that there needs to
be change in curricula and pedagogy in order to engage girls in science. Data
gathered in research in theme one was used to underpin the arguments for such
changes. Research discussed in theme two looked at girls’ learning styles and
interests, how teachers’ views and experiences impacted on pedagogy and at
interventions where curricula labelled as ‘gender inclusive’, ‘gender balanced’
and ‘girl friendly’ were trialled in the classroom.
The need to challenge the portrayal o f the nature and culture o f science as being
masculine, objective and difficult in order to attract more girls (and other
marginalised groups) into science was the focus o f theme three. Research
describing these issues and that they needed to be acknowledged by both teachers
and society before change could happen was described. Research investigating
teachers’ views on these issues was also described.
The final theme, identity and how there is a need to incorporate science into the
developing identities o f girls, will be discussed in more detail in the next chapter.
The reviews o f Blickenstaff (2005) and Brotman and Moore (2008) looked at
science education in general (as discussed in Chapter 1). In 2006 Murphy and
Whitelegg (2006a) produced a report for the Institute o f Physics reviewing the
literature on the participation o f girls in physics. They reviewed the literature
mainly from 1990 to 2005, but included earlier research if these studies had
important messages for the review or if the current literature was lacking. The
focus was on UK based research but non-UK based research was included to
widen the scope in some areas and if it was deemed to be transferable to a UK
context. Much o f the pre-16 research did, however, have an overall science focus
since many UK students study GCSEs in combined science rather than in the
separate sciences and the research was into GCSE science rather than the more
minority subject GCSE Physics. In all 177 literature sources were included in the
review.
Murphy and Whitelegg, after analysing the literature in their review, found that it
could be grouped into six themes that reflected the emphasis placed by
19
researchers and their work investigating the girls and physics ‘problem’. These
were:-
1. interests, motivation, course choices and career aspirations
2. relevance and curriculum interventions
3. teacher effects
4. single-sex schooling and groupings
5. measures and perceptions o f difficulty
6. entry and performance patterns in physics: the impact o f assessment
processes and techniques.
They found that the key determinants o f students’ attitudes to physics and their
willingness to study it post 16 were:-
1. how students saw themselves in relation to the subjects, both now and in
the future: their ‘physics self concept’
2. their experience o f school physics
3. a personally supportive physics teacher.
(Murphy and Whitelegg, 2006a, piii)
Murphy and Whitelegg themselves highlighted what they felt were important
issues from this literature review in a follow up paper in 2006 (2006b). They
reiterated that there were a number o f factors that influenced girls’ choice to
study physics post 16 and that there was no ‘quick fix’ to ‘the problem’ o f girls
and physics. They suggested that ‘a fundamental reconsideration o f the
contribution o f physics to students’ future lives’ (p300) is needed for change to
occur.
These three more recent reviews looking at girls and science and girls and
physics all highlight that ‘the problem’ is a complex one that has been
investigated from a variety o f different perspectives. They all show that focusing
on just one issue is not going to increase the number o f girls choosing to continue
to study science and/or physics or to choose to follow a science or physics based
career. A move towards looking at ‘the problem’ within the wider social and
20
cultural factors that make up the world o f today has started to emerge. These
reviewers encourage future work in the area to be carried out with this more
holistic viewpoint. It is intended that sections o f this thesis contribute to this
more holistic perspective.
These reviews provide a background to the rest o f this chapter. As Murphy and
Whitelegg (2006a) found, ‘there is little information about girls’ experiences of
science and physics in school in England and how this informs their attitudes and
future aspirations’ (pvi). I have therefore included non-English based research in
the following discussion where this supports and extends the English research
base.
General Attitudes to Science and Physics
Most o f the research into attitudes has been quantitative research with both boys
and girls and into science in general; only a few researchers have focused on
physics or reported findings on physics separately. Quantitative research can
generate large databases o f responses, effectively showing patterns in the data;
but they usually lack the depth to answer why pupils have a given attitude to
science. A limited number o f qualitative research papers have started to emerge
in the past 10 years, some o f which have followed a larger quantitative survey.
A major review o f the literature about attitudes to science was carried out by
Osborne, Simon and Collins in 2003. They reviewed 141 literature sources
concerning attitudes to science from 1980. They found that researchers were
giving increasing attention to the topic o f young people’s attitudes to science
which was driven by a recognition that all is not well with school science. In
general they found that young people’s attitude to science was not positive and
many were being alienated from the subject. Overall, they suggested that when
pupils take control o f their own learning, for example, by carrying out extended
investigation and discussion, they will have more interest in the subject.
However, they found that although a lot o f the research identified the problem,
21
there was not much that said specifically how the problem might be overcome.
An update o f this review was produced by Osborne, Simon and Tytler in 2009.
They identified five themes where work on attitudes had taken place in the
2000s. These were:
1. the measurement o f attitudes
2. engaging young people in science
3. gender
4. identity
5. large datasets.
There are many methods used in the research to both measure an attitude towards
science and to define what is meant by the term. Blalock et al. (2008) carried out
a review of 66 instruments for measuring attitudes. They found that many
researchers in this area used their own instrument and that these had not been
rigorously tested to establish their validity and reliability. If the results o f an
attitude measure are to have statistical value, then the instrument used needs to
meet the standards now expected from good psychometric measures.
For many years boys have consistently demonstrated a more positive attitude
towards science than girls. For younger children, i.e. primary children, it has
been found that there is no gender difference in attitude and interest in science.
The differences in attitude are formed in early secondary schooling and by the
age o f 14 most students have already decided whether they will pursue an
interest in science post compulsory schooling or not. A decline in a favourable
attitude is more pronounced for girls. However, this decline in attitude is usually
measured towards science in general, not for specific subjects or areas o f science.
Haste (2004) found that perceptions o f science related to personal, social and
ethical values. She found that for girls, the context, purpose and implications o f
science were important. Ethical factors related to science were a particular
positive factor for girls to improve their interest in science but were a negative
factor for boys. Masnick et al. (2010) also reported that students did not view
science careers as particularly creative or to involve interaction with others;
aspects that were important especially to girls when choosing future careers.
22
Research focusing on identity in science will be discussed in the next chapter.
The continuing worry about the number o f students studying science and
technology subjects post 16 and the impact this has on a country’s economy has
led to the funding o f national and international studies, for example, ROSE
(Relevance o f Science Education Project), TIMSS (Trends in International
Mathematics and Science Study) and PISA (Programme for International Student
Assessment). Attitude questions were included in each o f these surveys and data
from them can be used to analyse attitudes towards science for students from
many countries. Jenkins and Nelson (2005) report some o f the findings from
English schools involved in the ROSE survey. This showed that few students
liked school science better that other school subjects or aspired to become
scientists. Girls were more likely than boys to disagree that school science was
easy to learn. Girls also preferred non physical science topics. (These same
findings are reported by Quinn and Lyons (2011) in Australia). Using data from
PISA, Buccheri, Abt Gurber and Bruhwiler (2011) found the expected gender
differences in attitudes to the different science subjects between the genders were
also reported in four countries that they studied (Korea, Finland, Australia and
Switzerland).
An investigation o f attitudes using a longitudinal approach forms the basis o f a
small study carried out by Reiss (2004). He worked at one non-selective 11-16
school in southern England and followed 21 pupils in a mixed attainment science
group throughout their time in the school. He carried out interviews with the
pupils each year as well as lesson observations, teacher interviews and parent
interviews to explore their attitudes towards science and science lessons. For four
of the pupils he produced an in depth narrative o f their changing attitudes
towards science over time. He found that all four o f these pupils entered the
secondary school with an enthusiasm for science which dissipated over the next
five years. One o f the main influencers on these pupils’ attitudes towards science
was their teachers (see later section in this Chapter for more about teacher
influences on student choices).
The impact o f an extracurricular activity on pupils’ attitudes to science was
investigated by Barmby et al. (2008) in their paper about the impact o f the “Lab
23
in a Lorry” project. They surveyed 932 11-14 year old pupils about their attitudes
both before and after they were involved with the project. They also carried out
follow up interviews with 44 pupils at five schools involved with the project.
They again found that there was a steady decline in attitudes towards science as
pupils got older and that this decline was more pronounced for girls.
Research into attitudes towards particular science subjects rather than just
science altogether is less widely available. Spaull et al. (2003 and 2004) looked
at attitudes towards physics and biology with both secondary pupils and
undergraduates. Using the same questionnaire they surveyed 1395 school pupils
(both male and female) (selected from pupils in years 7 to 11 in six mixed
comprehensives in the North West o f England) and 439 first year undergraduates
(selected from English, physics and biology students) about their attitudes to
aspects o f biology and physics. This was a cross sectional rather than a
longitudinal study. They found that positive responses to liking physics dropped
from 64% in year 7 to 29% in year 11 with a corresponding increase in the
number who found physics boring. There was also a drop in liking biology but
only from 61% in year 7 to 52% in year 11. Pupils thought that biology was more
relevant to their everyday life than physics and was more likely to contribute to
solutions to environmental and medical problems. The English undergraduates
thought that physics was less attractive, less interesting and less likely to solve
problems than biology. Amongst the biology undergraduates there was a small
subgroup who also liked physics. Generally, however, the biology
undergraduates thought o f physics as a mathematical subject that was less likely
to solve problems than biology. As expected, 95% of the physics undergraduates
liked physics. Interestingly, 48% of them thought that males were better suited to
physics than females (see section later in this Chapter on stereotypes for fiirther
discussion on this topic).
A recent attempt at using a survey that also provided more detail was by Bennett
and Hogarth (2009). They devised a survey instrument asking about both school
science and science outside school that had two levels o f question. The level one
question was a straightforward statement (for example ‘If I had a choice I would
study physics’) to which the respondents answered agree, neither agree nor
24
disagree or disagree. The level two question then asked respondents to tick a
range o f reasons under their first response. The results showed that overall
positive attitudes to school science and science outside o f school decreased from
age 11 to age 16 with females being less positive than males throughout.
Attitudes to science outside o f school were generally more positive than to
school science.
Research on attitudes towards science in other countries has found similar results
to those reported above for UK pupils. For example Jones et al. (2000) and
Miller et al. (2006) working in the US found that girls have a less positive
attitude towards science than boys. Girls were found to be more people
orientated so, o f the sciences, found biology o f more interest to them. When they
did like science girls did so because they liked the teachers and also the subject
matter. Work by Baram-Tsabari and Yarden (2008 and 2011) in Israel and the
US looking at questions submitted to online science forums found that girls
submitted more questions about biology than boys whereas boys submitted more
questions about physical science topics.
In summary, the literature on attitudes towards science and physics reports that,
in general, young people’s attitudes become less positive as they get older with
the most rapid decrease in positivity occurring during secondary education. Girls
are reported as having a less positive attitude than boys. Attitudes towards
physics, in particular, are also found to be less positive than towards other
sciences. Many factors influence these attitudes including teachers and cultural
and social aspects o f how science is viewed. Attitudes towards science are
closely linked to whether a student chooses to pursue studying a subject or not.
The next section explores the choice literature but overlaps with the attitude
literature will be observed.
25
Choices
There are many reasons why girls do and do not choose to continue to study
physics post 16. Holmegaard et al. (2012), when discussing Higher Education
choices in general, highlighted that choice research in this area can be
categorised into three traditions. British choice research looks at understanding
how a student’s background, especially their social class, can affect choices and
access to Higher Education. This research uses both quantitative and qualitative
methods (for example, quantitative surveys and narratives (Reay, David and Ball,
2005); longitudinal case studies (Brooks, 2003); and focus groups (Read, Archer
and Leathwood, 2003)). American choice research is mainly quantitative and
makes use o f comprehensive choice models (for example, Eccles et al. (1983))
that investigate how ethnicity, gender, social class and prior high school
trajectories impact on choices. The tradition in Scandinavian research (for
example the work o f Holmegaard et al. and Boe et al. (2011) described below) is
to relate student choices to their construction o f attractive identities. They argue
that choice is socially constructed in society in general. These traditions can also
be found in choice research looking at subject choices before Higher Education.
As described by Holmegaard et al. (2012), American research on choices makes
extensive use o f choice models, one o f the most popular being the expectancy-
value model o f achievement related choices (Eccles et al., 1983). This model,
grounded in social psychology, has been used to investigate enrolment in college
mathematics and English courses (Eccles, Vida and Barber, 2007); to high school
course enrolment in mathematics and science (Simpkins, Davis-Kean and Eccles,
2006); and choices in relation to physical science, engineering and applied
mathematics (Eccles et al., 1999) to give a few relevant examples. The
expectance-value theory is based on the idea that an individual’s choice,
persistence and performance can be explained by their beliefs about how well
they will do in an activity and the extent to which they value that activity
(Wigfield and Eccles, 2000). More recently, Eccles (2009) has come to think o f
identity as a motivational construct. This then forms a link between this
26
expectancy-value model and identity formation, a concept that is discussed in
more detail by Boe et al. (2011).
Boe et al. (2011), working in Norway, discuss how the various aspects o f the
expectancy-value model are linked to not only identity, but self concept and the
society as a whole. They focus on five aspects o f the model and relate them to
STEM choices.
1. Interest enjoyment value
That young people have a low interest in school science subjects and
that boys and girls interests differ
2. Attainment value
That many young people cannot see themselves as ‘science people’
especially young women who see science identities as not attractive to
them
3. Utility value
That STEM subjects can be gatekeepers to careers and that the
hardness o f science will be tolerated if they are useful for the future;
however, girls especially worry about failure (they have a lower self
efficacy)
4. Expectation o f success
That physical sciences and mathematics are seen as hard and
achievement is linked to self efficacy
5. Relative cost
That the physical sciences and mathematics have a high cost due to
difficulty. This is a negative aspect o f choice. Girls also see a cost in
male dominated areas
Using this discussion o f the Eccles et al. model, Boe (2012) found that when
choosing subject programmes, the Norwegian students wanted one that would be
interesting, meaningful and self realising. Of the five components, utility value
was especially important for science students and was higher for girls than for
boys. Looking specifically at physics students, Boe and Henriksen (2013), found
that they could be categorised into three groupings. There were those who chose
27
physics for both intrinsic and extrinsic motives (interest, utility value,
expectation o f success and a fit to personal beliefs); those who focused on
extrinsic motives (highly valuing the utility value o f physics but having a low
interest); and those who chose it for intrinsic motives (interest, self realisation
but low interest in the utility value). They found that more students from the
intrinsic category went on to study physics at university than from the other two
categories and that this category was the one with fewest females in it.
Positioning their work within the Scandinavian tradition, Holmegaard et al.’s
(2012) own work on identity and choices focuses on two areas. These areas are
that young people make free choices but with limitations and that their choice is
an individual responsibility but one that is socially embedded. A young person’s
choice o f what to study for Higher Education is exciting but there is an anxiety
about making the ‘right’ choice. This choice is made from a combination o f
interests and that the subject chosen will lead to a fulfilling career. Young people
want to choose something for themselves but they also want that choice to be
meaningful for their family and friends. When looked at through this lens, choice
becomes part o f the identity work that young people participate in.
Choices linked to future careers
Woolnough (1994) proposed that choices were based on three factors - in school
factors, out o f school factors and personality. How teachers and teaching
influence students’ choices will be discussed later, as will personality or identity
development. One o f the out o f school factors that is often quoted as influencing
choice is the relevance o f science or physics to a future career; similar to the
utility value o f science subjects identified in the Eccles et al. (1983) choice
model.
Stewart (1998) carried out a small survey (128 students) o f students who had
already chosen to study A-level physics, looking at differences in attainment,
attitude to and opinion o f syllabus content. She found that girls who chose to
28
study A-level physics tended to be higher attaining than boys, were mainly
studying physics as an aid to entering a caring profession (e.g. medicine) and
enjoyed physics being taught in context. Williams et al.’s (2003) work with year
10 students showed that for those who found physics boring this was not only
because it was hard (see below) but also because they did not find the subject
relevant to either themselves or for their future careers.
The students who participated in Pike and Dunne’s (2011) interviews made it
clear that their post 16 choices had been made based on their future educational
and career pathways as well as their experience o f secondary school pedagogies
and the differentiation o f subjects by difficulty. They were not willing to pursue a
subject if it did not fit into their future educational and career pathway. Cleaves
(2005) also found that the students she worked with made their future science
choices linked to their knowledge o f science careers.
The aspiration to pursue a career in science is often formed at an early age. The
ASPIRES project (DeWitt et al., 2013) investigated the formation o f future
science aspirations in year 6 pupils in England. They found that girls, pupils o f a
mixed ethnicity and pupils with a low cultural capital had lower aspirations in
science than other groups o f pupils. The aspiration to pursue future study o f
science and a future career were closely linked to attitudes to school science,
science self concept and parental attitudes. Research in the US by Tai et al.
(2006) confirms that early aspirations are linked to future science study. They
found that, if at the age o f 13 a student expected to have a science career at the
age o f 30, they were 1.9 times more likely to get a life science degree and 3.4
times more likely to earn a physical science degree than those students who did
not have the same aspirations.
In summary, intended career choice is often found to be a dominant factor in
future subject choice. If a child has formed an aspiration to pursue a scientific
career at an early age then they are more likely to choose to study the sciences
later in their academic career than those who do not hold this early aspiration.
Boe et al. (2011) found that amongst Norwegian students who chose to study
physics, especially girls, many o f them chose it for its perceived utility value; it
29
was seen as a gatekeeper subject that was useful for many careers. However,
only a small number o f those who chose physics for this reason went on to study
it at degree level. The majority o f students who chose to study physics at
university not only wanted a future career in the area but enjoyed the subject as
well.
Influences of Teachers and Teaching
As pointed to above in research about why students do or do not choose to study
science and/or physics post 16, another major factor identified is the influence
that significant others, including teachers, have on that choice. It can be argued
both that students choose to continue to study a subject if they have an interest in
that subject (as outlined above) and that, in schools, it is the teachers who are the
main people who will influence whether an interest in a subject is fostered or
diminished. The teacher effects can be looked at from two directions - one the
teaching techniques used in the lessons and secondly the personal interactions
between teachers and pupils.
Osborne and Collins (2001) investigated pupils’ views o f the science curriculum.
When pupils express their views about the science curriculum they also tend to
express views about how aspects o f that curriculum are taught. Osborne and
Collins used focus groups to research pupils’ views. They conducted 20 focus
groups with 144 16 year olds. They chose to use focus groups, although these
had not been used extensively in science education research in the past, to
research insight into the experience, views and beliefs o f pupils. They argued that
data gathered from focus groups is often a more accurate reflection o f individual
views as opposed to data from an individual interview where the pupil being
interviewed may tell a ‘story’ to please the interviewer.
The pupils said that their interest in science classes was maintained by teachers
who made the lessons ‘fim’, either through their methods, or presentation o f
material, or through the organisation o f work which immersed pupils in practical
30
activities. Girls also identified those teachers who devoted time during a lesson
to clarification o f content, and those who built up a good relationship with their
pupils by giving opportunities to raise questions and discuss aspects o f science as
those who maintained their interest. Weaker teachers were identified as those
who relied on ‘writing on the board’ and text books.
In their 1989 study, Tobin, Deacon and Fraser (1989) used a case study approach
to investigate an example of, what they identified as, exemplary physics teaching
in a High School in Perth, Australia. They observed one teacher teaching his
grade 11 physics class for 12 lessons and then interviewed selected students and
the teacher about the observed lessons. Although this is a report o f just one
teacher and how he taught his physics class, it gives a good starting point for
investigating what a good and effective physics class looks like and the activities
that could be used to achieve this. Overall, four points were identified by these
researchers as having an impact on the students' learning. These were:
1. the teacher's belief that students should be mentally active in order to
learn with understanding
2. that the teacher used strategies to facilitate student understanding o f
physics concepts
3. that the external examination influenced the implementation o f the
curriculum
4. that the learning environment that prevailed in the teacher's physics class
was viewed favourably by students.
(Tobin, Deacon and Fraser, 1989, p i46-148)
No in-depth details are given o f the specific teaching strategies used to facilitate
student understanding as highlighted in point 2. The only indications o f these are
two comments that the teacher encouraged the students to work independently in
small groups and that he used investigative experimental work.
Studies in European countries have also looked at the issue o f physics teaching
and physics teachers. These include work carried out in Norway by Angell et al.
(2004) and in Switzerland by Ladubbe et al. (2000). In their study in Norway,
31
Angell et al. (2004) investigated pupils' and teachers' views of physics and
physics teaching. They used a combination o f questionnaires and focus groups to
gather their information. Their questionnaires were given to a random sample o f
grade 12 and 13 pupils studying physics (2192 pupils); to a random sample o f all
grade 12 pupils (1487); and to 342 physics teachers in upper secondary schools.
The questionnaires contained a mixture o f open and closed questions. Following
on from the questionnaires, focus groups with selected grade 12 and 13 physics
pupils were conducted. These focus groups were segmented according to gender
to facilitate sharing o f perceptions. Overall, they found that pupils found physics
interesting but demanding, formalistic in nature, but still describing the world.
Girls had different demands from boys about what helped their understanding o f
physics; they emphasised context and connectedness. All pupils, but especially
girls, liked studying topics such as relativity and astrophysics. In the actual
classroom, all pupils indicated that they would like to see a stronger emphasis on
qualitative or conceptual approaches (for example, discussions and
demonstrations) and more student centered teaching (for example, using pupils'
suggestions in the lessons, letting pupils choose problems and methods in
experiments, group problem solving, project work). They also indicated that
variety was essential for good teaching. Although there was not much difference
between girls and boys in this research, girls did show a higher preference for all
o f the above and also 'cookbook' experimentation. These results came mainly
from the questionnaires with the focus groups being used as a triangulation
method. No details o f the descriptions given to explain the questionnaire answers
were given.
In Switzerland, Ladubbe et al. (2000) carried out a quasi-experimental study
looking at both teaching strategies and teacher behaviour in physics. Their study
was with students in upper secondary schools who were all taught by teachers
with Masters degrees in physics, mathematics or science but only basic education
qualifications. They chose a positivist approach to their study as they felt this
would be most acceptable to teachers trained in the physical sciences. The core
of their investigation was a range o f classroom interventions and involved 25
32
teachers and about 600 students. The quasi-experimental approach consisted o f
four groupings o f teachers and their classes:
Group 1 full involvement with training and development of
materials for teachers
Group 2 use o f materials and training for teachers
Group 3 use o f materials but no training for teachers
Group 4 control
To test the interventions, they did a preliminary survey with all the students, gave
tests at the end o f the topic units covered by the intervention and gave all
students and teachers a final survey. Overall, they found that girls' attitudes to
physics could be improved by a collection o f teaching strategies. The most
effective were integration o f individual preconceptions, student-orientation,
physics as an experience, student discussion and using everyday physics as
examples. They also looked at teacher-pupil interaction. Their results indicate
that a physics teacher has a key role to play in all students' attitudes and
achievements in physics, not just for girls. They found that there was some
evidence from teacher questionnaires and interviews that during training for the
implementation o f the classroom interventions, teachers increased their
knowledge o f and sensitivity to gender issues. These came into play when
implementing the teaching strategies involved in the interventions.
Much o f the early research about teacher-student interactions has been focused
on the time spent by the teacher with each student. In a meta analysis o f research
about the time teachers spent with students in all subjects, Kelly (1988) found
that, on average, teachers spent 44% of their time with girls and 56% with boys
with the biggest differences in time being observed in science and social science
subjects. However, it is not just the time that a teacher spends with a pupil that
can influence how they feel about a subject but the more personal interactions
that take place both inside and outside o f the classroom.
In 2005 Krogh and Thomsen (2005) reported on part o f a large, longitudinal
study o f physics in the Danish upper secondary school system. They reported on
33
phase 2 o f the study where 789 students were selected to complete a
questionnaire on ‘Possible influences in students’ attitudes towards physics and
choice o f A-level physics’. The survey was given when students had just decided
which subjects they would take for A-level. 45 o f these students were
interviewed, using semi-structured interviews, to collect supporting evidence.
Their study showed that students would like their teachers to take more interest
in them as persons, for example, by using less transactional communication
styles and simply by being more off task in the classroom.
The relationship between students’ attitudes to science and teachers taking an
interest in them as persons is also reported in Wubbels and Brekelmans (1997).
Wubbels, Creton and Hooymayers (1985 cited in Wubbels and Levy, 1993)
developed a model to map teacher interpersonal behaviour based on a model
used in clinical psychology and psychotherapy, originally developed by Leary in
1957. This model has eight different behavioural aspects: leadership,
helpful/friendly, understanding, student responsibility and freedom, uncertain,
dissatisfied, admonishing and strict. An instrument to measure students’ and
teachers’ perceptions o f interpersonal teacher behaviour was developed by
Wubbels and Levy (1993) based on extensive interviews with students about
their perceptions o f the teacher. This instrument gives scores for each o f the eight
teacher behaviours based on responses to questions, using a five point scale.
Wubbels and Levy report that for classes to be effective they should become
more student centred, that teachers should give their students more responsibility
and act in an understanding way.
Fisher and Rickards (1998) used the same model and a very similar questionnaire
to investigate teacher-student interpersonal behaviour and student attitude to
mathematics in Australia (21 teachers in 9 schools and 405 students in grades 8,
9 and 10). Student attitudes to mathematics tended to be higher in classrooms
where the students perceived greater leadership and helpful/friendly behaviour in
their teachers. A better attitude to the subject is seen as an indication that
students will be more willing to continue to study the subject post 16 (see section
on choices). Fisher and Rickards feel that the assessment o f interpersonal
behaviours could be as important as teacher personality traits and teaching style
34
in describing an effective mathematics teacher. Further research using the model
and questionnaire was conducted by Levy et al. in 2003. They carried out a
survey o f 3023 students and 74 teachers in 168 classes in 7 secondary schools in
Washington DC. They found that 10% o f the variance in student perception o f
teachers could be explained by student and teacher gender and ethnicity, student
age, class size, the subject taught and the experience o f the teacher. More
research is needed into these areas, specifically in physics, if more is to be
understood o f the complex and interactive nature o f students’ perceptions o f
teachers and the learning environment.
In summary, the body o f research reviewed in this section demonstrates how
important a teacher and their teaching can be in influencing a pupil’s attitude
towards their subject and their future choice as to whether to study that subject or
not. Pupils report that they enjoy lessons that are fim and where they carry out a
variety o f activities that are student focused including opportunities to discuss the
subject content. Pupils appreciate it when teachers take time to clarify the content
which allows them to understand the concepts being presented. Pupils report that
their best teachers are the ones who build up a good relationship with their pupils
and are interested in their pupils as people. It is with these teachers and in these
lessons that pupils find an enjoyment o f the subject and decide whether or not to
pursue that subject further.
Additionally, it is not only individual teachers but the whole school ethos that
can influence the uptake o f subjects post-16. Reporting on their study into post
16 physics and chemistry uptake, Bennett and her co workers (Hampden-
Thompson, Lubben and Bennett, 2011 and Bennett, Lubben and Hampden-
Thompson, 2013) describe the factors they found at schools where uptake was
the highest. They found the highest uptake at schools where there was a positive
school ethos towards physics and chemistry, where there was stable
management, where there was a diverse GCSE offer, where there were specialist
physics teachers, where exam grades necessary for progression were at grade B
or above, which offered subject specific careers advice, structured work
experience and extra curriculum career experiences, and where pupils were
encouraged to be ambitious and empowered. However, they did not take account
35
o f the socioeconomic make up o f the schools or the ethnicity o f the pupils which
could have influence on how the school ethos developed.
Influences of Others
Moving away from teachers and to other significant people, Sjaastad (2011)
reported from his work with 5077 Norwegian undergraduates that parental
influence was reported by 22% o f respondents as having played a role in their
subject choice. Work in the US by Tenenbaum and Leaper (2003) and Bhanot
and Jovanovic (2009) investigated the links between parental behaviours and
beliefs and children’s science interests and abilities. Looking at conversation
within the family, Tenenbaum and Leaper found that parents o f daughters
believed that their child was less interested in science than parents o f boys and
that science was more difficult for girls than boys. These beliefs were found to
predict the children’s interest in science since the parents transmitted these
beliefs to their children. Bhanot and Jovanovic (2009) found that parents o f boys
believed that they had a higher ability in science and that science was more
important for them in the long run. For girls, it was mothers who had the greatest
influence on their daughters. Girls were found to have a more positive attitude to
science when they had discussions with their mothers about the important o f
science.
The influence o f family on the decision to become scientists was also observed
by Gilbert and Calvert (2003) in their work in New Zealand. The five women
scientists whom they interviewed all reported that their mothers had influenced
their choice to study science. Most o f them also commented that they wanted to
be like their fathers but also to have a fuller role within their family as their
mothers did.
The influence o f peers must not be forgotten. Stake and Nickens (2005) reported
that girls tended to have less peer support for their science interests than did
boys. In their work with 161 female and 163 ‘gifted’ US high school students
36
who took part in a science summer programme they found that students who
reported having positive science peer relationships were associated with more
positive images o f themselves as scientists.
A recent wide scale project looking at participation in mathematics and physics
(UPMAP - Understanding Participation in Mathematics and Physics) has started
to report findings from both its quantitative and qualitative strands. Although the
project investigated attitudes to and choices about these two subjects together,
the large research base allows findings to be reported separately for each subject.
Reporting on one o f the qualitative strands o f the UPMAP project, Rodd, Reiss
and Mujtaba (2012) found that physics undergraduates reported that they had
come to physics because o f a relationship with key people in their past. Rodd,
Reiss and Mujtaba speculate that this may be different from those who choose
humanities. They suggest that in, for example, English, students develop a deep
involvement with their favourite literary characters. These characters become
part o f them and the students start to think and feel as these characters would. In
physics, it is actual people, not fictional characters that form these relationships.
In summary, the research shows that parents, peers and other adults can all be
significant in influencing pupils’ future subject choices. For girls, the evidence
shows that mothers can be particularly significant.
The Image of Physics
When pupils are asked to describe a physicist, or a scientist, the general response
has been that they are a White, middle class male. When asked to talk about the
subject physics, the response has been that it is a masculine subject that is hard.
These are the commonly held, stereotypical views o f science and scientists and in
particular physics and physicists. Ryan (2011) calls these views ‘commonsense’
ideas about subjects that produce and reproduce the gendered understandings
about what is appropriate and natural for male and female interests and subject
choices.
37
For many years, the physical sciences and mathematics have been perceived as
being masculine and the arts as being feminine. This is clearly described as a
binary dichotomy by Francis (2000) e.g.
male female
rationality emotion
objectivity subjectivity
science nature
hard soft
the sciences the arts
These ideas about what is ‘natural’ for boys and girls are formed at an early age.
In one paper from the recent ASPIRES project, Archer et al. (2013) looked at
primary school girls and their parents’ constructions o f science aspirations. These
results were from phase one o f the project where 9319 year 6 pupils (50.6% boys
and 49.3% girls) across England were surveyed. Supporting evidence came from
170 interviews with 78 parents and 92 pupils from 11 schools. Their results
showed that girls constructed science careers as masculine and incompatible with
their performances o f popular femininity. This meant that they found science
aspirations unthinkable. These perceptions were exacerbated by social class with
working class girls having the most negative constructions.
Stereotypical views are linked to images o f self. Breakwell et al. (2003) found in
their study o f 1140 UK 11-16 year olds (570 boys and 570 girls) that the reported
image o f a girl who liked science was o f one that was less feminine than
‘normal’. The notion that liking science and/or physics is less similar to most
young people’s self image is also the basis for the work in Germany and Holland
by Hannover and Kessles (2004), Kessels et al. (2006) and Taconis and Kessels
(2009). Hannover and Kessels (2004) reported that science and mathematics
students were matched with the least-liked subject prototypical student for thetVi thmajority o f 8 and 9 grade German students. Students did not relate to physics
and mathematics students because they thought they (physics and mathematics
students) were less physically and socially attractive, more isolated, less creative
and less emotional than them. Kessels et al. (2006) looked specifically at the
38
tilimage o f physics. They found that 63 German 11 grade students associated
physics (compared with English) as difficult, for males and heteronomous. The
attitudes amongst those students who had dropped the study o f physics, as
expected, was more negative than those who were still studying it. Girls also held
a more negative view o f physics than boys. Taconis and Kessels (2009) study ofih54 Dutch 9 grade students confirmed the views o f science and physics held by
students in other countries. They also found typical peers who liked science as
less attractive, less popular, less creative, less emotional, more intelligent and
more motivated than peers who favoured the humanities.
Research in the US by Baker and Leary (2003) also found that issues o f
stereotypes played a role in girls’ subject choices. They carried out a small scale
qualitative project asking girls at various stages o f their schooling career to tell
them about their feelings about science. These girls all volunteered to take part in
the project. These girls were confident in their ability to be successful at science.
However, even though they disagreed with the idea that girls cannot do science
or be scientists they also made stereotypical negative statements about girls and
science especially about physical sciences.
Changing stereotypical views o f scientists by using role models has been
suggested as a possible method for encouraging more girls to study science.
Buck et al. (2007) investigated how a small group o f 13 girls in the US and 8
women science graduates who had volunteered for a school outreach programme
came to decide what made a good role model. The girls felt that a good role
model was someone they could feel a deep connection with and that these
usually came from within the family. They did not initially see scientists as role
models (they felt they were ‘too geeky’) and it was not until they had got to
know the women scientists that they started to relate to them. The issue o f the
gender o f the role model varied from girl to girl, but they all agreed that whatever
the gender they needed to personally connect with the scientist for it to make a
difference. The women acting as role models felt that gender matching was
important. They initially thought that the role model was there just to help the
students like science but came to realise over the time o f the intervention that this
would only happen when personal interactions took place as well.
39
Recent work by Betz and Sekaquaptewa (2012), also in the US, has found that
female STEM role models can in fact demotivate middle school girls. This is
because women who work in STEM can be seen as impossibly successful
especially for girls who are already uninterested in science at this age. These
women are perceived as having less feminine traits than normal, and for
uninterested girls this possible future self is so far removed from their present
self that they feel threatened rather than motivated.
The work of Cleaves (2005) also focused on stereotypical views o f science
students but linked the views o f individual students with the stereotypical images
of others. She found that not all students who went on to study science could be
classed as stereotypical science students i.e. those who had committed to science
from an early age. Other students who chose science had not made the decision
to study science at such an early age and held less committed views on what to
study. Their choices were influenced by their self perception o f science and their
knowledge o f science careers.
Ong’s (2005) work with young women o f colour who were working in the
physics department o f a large US research university found that they tried to
overcome the gender stereotypes expected o f them by the act o f fragmentation.
This meant that they displayed, or performed, White and masculine traits so that
they would be accepted in the workplace. This performance o f different identities
(see Chapter 3) in order to survive in the science workplace was also observed by
Gilbert and Calvert (2003) with their work with female scientists in New
Zealand.
Work in the ASPIRES project also looked at how the stereotypical view o f
scientists influenced children’s engagement with it. Wong (2012) studied two 13
year old British Asian girls who could be classified as high achieving. One o f
these girls, who was in the top set for science and wanted to study the three
separate sciences at GCSE and then move on to a possible science career, did not
show any particular interest in the subjects but saw them as allowing others to
see her as clever and smart. The other, who was also in the top set, did not like
science, hated physics and was more interested in her looks than being
40
recognised as being smart. Another strand o f the ASPIRES project looked at
parents’ and primary children’s constructions o f who engaged with science
(DeWitt, Archer and Osborne, 2013). They found that about half o f the
interviewed parents described scientists in a stereotypical manner, that o f being a
‘geek’ or a ‘nerd’. Few o f the children however agreed with this image. Over half
o f the children described scientists as being clever and thought that their science-
keen peers fell into this category. The remaining children saw scientists as
normal, but very few parents described scientists in this way. Further analysis o f
the children’s interviews (Archer et al., 2012) found that o f those girls who did
identify with science at the age o f 10/11 they were already having to balance
their science aspirations with performance o f popular heterofemininity to make
those identities ‘thinkable’.
As identified above, one often quoted belief about physics is that it is a hard
subject. Lyons (2006) identified this as one o f the themes that emerged from
reviews looking at attitudes to science (the others being the transmissive
pedagogy of school science and the personal irrelevance o f science curriculum
content to pupils). Physics was perceived as being the most difficult science
followed by chemistry and then biology.
Students in Bennett and Hogarth’s work (2009) showed a marked reluctance to
study physics because it was perceived as hard. The work o f Pike and Dunne
(2011) looked at this discourse o f hardness. They recognised the paucity o f
research using a more exploratory approach for investigating choice so carried
out a mixture o f one to one and focus group interviews with students who had
just made their post 16 choices. They found that there was a dominant discourse
of subject differentiation into a hierarchy o f difficulty with science and
mathematics being seen as hard subjects. They also found that students
positioned themselves as being capable or not capable o f further studies o f these
subjects.
A small scale survey research project by Williams et al. (2003) carried out with
317 year 10 (aged 14-15) students, found that one o f the reasons that students
found physics boring was because they found it difficult. A study by Stokking
41
(2000) carried out in Holland found similar results. He carried out surveys with
1371 students over a two year period. Overall his results showed, amongst other
results, that female students scored significantly higher on their perception o f
physics difficulty. This was one reason why female students less often chose to
study physics later in their secondary school career.
Students who like a ‘hard’ subject such as physics are also perceived to be less
popular and less socially acceptable than their peers. Francis et al. (2010)
investigated how some high achieving pupils also managed to be popular with
their peers. Popularity is a complex and slippery concept. Popularity does not
always mean the most liked as it also contains aspects o f influence and sources of
admiration and someone who is popular with one group may not be with another.
However, popularity is a concept that is recognised in schools. Francis et al.
looked at 71 high achieving year 8 pupils in nine schools in southern England. Of
these 71 Francis et al. found a sub group o f 22 pupils that were both high
achieving and popular as identified by other pupils on a survey. These high
achieving popular pupils were generally good looking, fashionable and sociable.
These pupils produced both normative performances o f gender but also dialogic
performances containing aspects usually associated with the other gender. For
example, boys could be seen to be engaged in the classroom by working hard and
completing classrooms tasks (normally associated with girls) and girls as being
assertive and confident (normally associated with boys).
These dialogic performances o f gender, performances that include aspects
usually associated in a binary dichotomy with the other gender, have been used
to discuss how girls come to choose subjects especially where there is a tension
between how they see themselves and in doing subjects that are considered
masculine. Mendick (2003 and 2006) used the term ‘female masculinity’ to
describe girls who chose to study A-level mathematics. Francis (2010) describes
gender as monoglossic and heteroglossic. The monoglossic interpretation o f
gender is that based on a binary where the male is masculine, objective, strong
and active and the female is feminine, emotional, weak and passive.
Heteroglossia exists within the monoglossic system and describes micro level
contradictory productions of gender. Francis argues that the terminology female
42
masculinity can only be applied to a small number o f girls who display many
male attributes whereas heteroglossia can be used to describe many more
behaviours where girls have a macro femininity but micro masculine
contradictions as seen in her study o f high achieving pupils described above.
This section on the image o f physics describes how the generally held view o f
physics is that it is a subject studied by White, middle class, males, that is hard
and boring. This perception o f physics is formed during early childhood and girls
report that the image o f physics and physicists is not compatible with their self
image. They see girls who like physics as being less feminine than them. It has
been found that female role models can help to change this image, but only when
personal interactions take place, otherwise girls see female physicists as being
too different from themselves to be an identity that is achievable. Women
working as physicists often report that they perform ‘as expected’ in the
workplace. They display more masculine traits in order to be accepted.
Conclusion
The research discussed in this chapter indicates that young people’s overall
attitudes to science is generally not positive (Simon and Collins, 2003 and
Jenkins and Nelson, 2005) with girls being less positive than boys (Bennett and
Hogarth, 2009). Attitudes towards science change most in secondary schooling
(Reiss, 2004) with the decrease in liking for physics being more pronounced than
for biology (Spaull et al., 2003 and 2004).
Choices as to which subjects to study after compulsory schooling are influenced
by future careers, teachers and teaching and significant others. Future career
choice is often a major influencer o f subject choice (Woolnough 1994, Pike and
Dunne, 2011 and Cleaves, 2005) with early formed career aspirations in science
often leading to persistence o f choice (Tai et al., 2006). The literature reports that
good teaching leads to enjoyment o f the subject which often leads to associated
subject choice. Examples o f this specifically for physics can be found in Tobin,
43
Deacon and Fraser, 1989, Angell et al., 2004 and Ladubbe et al., 2000. The
teachers themselves and how they interact with the students in their classes also
influence choice with good personal interactions leading to a more positive
attitude in students (Krogh and Thomsen, 2005 and Fisher and Richards, 1998).
For all students parental influence is important when considering future choices
(Sjaastad, 2011) and for girls, the mothers’ influence is particularly important
(Gilbert and Calvert, 2003).
One particular issue for the choice as to whether to study physics further is the
stereotypical held view that physics is hard. Since physics is perceived as being
hard, many students are reluctant to study it (Bennett and Hogarth, 2009 and Pike
and Dunne, 2011). Girls who like physics are perceived by others as being less
feminine (Breakwell et al, 2003 and Cleaves, 2005). This image o f physics is
experienced as a less attractive image than for many other careers and does not
match with the self image o f many girls (Hannover and Kessels, 2004). Girls
who do like physics and science and remain popular with their peers are
generally good looking, fashionable, and sociable and perform both normative
performances o f gender but also dialogic, non-normative performances (Francis
et al., 2010).
As can be seen, the question ‘why choose physics’ is a complex one that involves
many interrelated issues. The research shows that the main influencers o f choice
are subject enjoyment, usefulness o f the subject (for example to future career or
self), the influences o f significant others including teachers and prior
achievement which are all linked to identification with the subject. Included in
this identification with physics are self concept/self efficacy and the image o f
physics that points to the stereotypical view that physics is a hard subject that
only White males can do. These views o f physics are formed early in life (Archer
et a l, 2013).
Murphy and Whitelegg (2006a) identified a key determinant as to whether girls
choose to study physics post 16 is ‘how students saw themselves in relation to
the subject, both now and in the future; their physics self concept’ (piii). How
girls see themselves in relationship to physics can also be called their
44
identification with physics. Brotman and Moore (2008), when looking at the
underlying concepts o f science education research, identified that a focus on
identity was becoming more prevalent. Even though identity has been identified
as a focus for recent research in science education, this is still a developing area,
especially in the UK. Research about what a science identity is and how it
develops has been carried out mainly in North America. Research relating
science identity to choice is limited.
Many o f the topics outlined in this chapter contribute to one’s identity
development. For example, girls do not see themselves as a ‘physics type o f
person’ because this is contrary to the image o f physics that is held by many in
society. A poor attitude to science can develop because science is seen as a hard
subject to which only a privileged few can aspire. A lack o f a positive attitude to
physics and a feeling that it is not for them leads to a choice not to study the
subject when it becomes non compulsory. Rather than looking at these in
isolation, bringing them together in a study o f science/physics identity
development and how this impacts on choice could give a more holistic view o f
how young people decide on their futures.
Much o f the research into subject choices, attitudes to science and the image o f
physics has been done using quantitative methods but it has been recognised, as
identity and self concept/self efficacy become more important factors to
investigate, that qualitative methods may result in more detailed knowledge
about choices. Qualitative research can give a thick description o f why young
people are making the choices that they are, why they have a certain attitude
towards science and physics and why they see physics in a certain way. This
move towards adopting qualitative research methods when investigating choice
has influenced my research design that is discussed in Chapter 4.
45
Chapter 3 A Developing Framework for Identity
and Self Efficacy
Introduction
In this chapter I develop a framework for identity and self efficacy that I use to
investigate girls’ physics choices. Previous researchers looking at science
identity have described it as ‘who we think we must be to engage in science’
(Calabrese Barton, 1998, p380). This description involves considering broadly
who students are and why they choose, consciously or subconsciously, to engage
or disengage with science in a classroom setting (Shanahan, 2009). However it is
often the case that in the literature focused on gender and science the conceptions
o f identity and, to some extent, self efficacy are under theorised.
I start the chapter by presenting a theoretical position on identity drawing on the
theoretical perspectives proposed by Jenkins (2008) and Gee (2000). Once this
working description o f identity is presented, I draw on the theoretical discussions
of communities o f practice (Lave and Wenger, 1991) and figured worlds
(Holland et al., 1998) to develop a position on where and how science, and in
particular, physics identities are developed. Both communities o f practice and
figured world theories have been used in the literature to describe girls’
relationships with science and physics. In this chapter I interrogate this literature
base and discuss outcomes from it that can help us to understand how girls come
to make their choices about whether or not to study physics post 16.
Traditionally self efficacy and identity have been investigated separately. Identity
research in education is mainly from a sociological and qualitative perspective
whereas self efficacy research is predominantly psychological and quantitative.
Originally my research focused on identity and self efficacy as two stand alone
constructs. As I developed my thinking and understanding about the two topics, I
came to view self efficacy as one component o f identity and that the two needed
46
to be investigated as such. Following the discussion o f figured worlds in science
identity literature, I briefly introduce self efficacy and some o f the relevant
literature before suggesting how the two can be linked by closing the chapter
with a look at how narrative has been used in identity and self efficacy research
and how this informed my methodological choices.
Developing a Framework for Identity
Researchers in many fields have used identity as a basis for investigating society.
However, the term identity has taken on a range o f meanings in this literature,
including in the education arena. In this introductory section, before I interrogate
the literature about “science identity” specifically, I describe how I came to the
description o f identity that I will use in my research.
I drew on four theoretical perspectives on identity in order to develop the
perspective on identity used to analyse the data gathered on girls’ relationships
with physics and their subsequent choices. The first two o f these four theoretical
perspectives are those proposed by Jenkins (2008) and Gee (2000) and are used
to develop my understanding o f identity whereas the second two proposed by
Lave and Wenger (1991) and Holland et al. (1998) provide a way o f describing
how we come to that identity.
What is identity?
Jenkins (2008) proposes that
identity is the human capacity to know who’s who. This involves
knowing who we are, knowing who others are, them knowing who we
are, us knowing who they think we are and so on. Identity is a process
(identification) not a thing. It is not something that one can have or have
not, it is something that one does. (p5)
47
This description o f identity involves both self and collective components. Jenkins
further argues that these cannot stand alone. The work o f identity, identification,
is
the systematic establishment and signification, between individuals,
between collectives, and between individuals and collectives, o f
relationships o f similarity and difference, (pi 8)
Proposing this theory, Jenkins goes on to argue that the identity o f any individual
is not meaningful if isolated from the rest o f the world and from other humans.
We cannot “do identity” in a social vacuum. Each individual is unique, but this
uniqueness is socially constructed. Individual identity formed at an early age (for
example, kinship, ethnicity) is likely to be less changeable than that formed later
in life although change is fundamental to identification.
All identities are constituted through the process o f ‘the internal - external
dialectic o f identification’ (p40). This means that with our identity work, what
others think o f us is as important as what we think o f ourselves. When we send
out signals about who we are, it is, in part, how those signals are interpreted by
others that gives us our identification. The problem is that we cannot control
what others think o f those signals nor how they interpret them. This can result in
differences between how we see ourselves and how others see us even though
both o f these contribute to who we understand ourselves to be.
Jenkins description o f identity as a combination o f both self and collective
resonates with my own thoughts on how we come to be the type o f person (or
persons) that we are, dependent on the context we are in. His use o f the term
“know” in his first description o f identity perhaps goes too far - do we ever
really know who we are, know who others are or know who they think we are?
This would perhaps be better described in terms o f thinking we know who we are
and so on.
The second perspective on identity is from Gee (2000). Gee describes identity as
‘the kind o f person (you are) in a given context’ (p99). This perspective means
that people can have multiple identities connected to how they perform in
48
society. Gee offers four ways with which to view what it means to be a certain
kind o f person: nature identity, institution identity, discourse identity and affinity
identity. The identity o f each kind o f person is viewed in terms o f where that
identity comes from, who has the power to identify it and who has the power to
maintain it.
At the heart o f this identity theory is the idea that individuals are recognised by
others as a specific kind o f person. An individual needs to be seen by others in
certain ways for their identity to be recognised. This can only happen if there are
people who can recognise certain identity traits in certain ways. This interpretive
system can be historical and/or cultural; the rules o f an institution; discourse
between people; or the working o f an affinity group (a group where members
have allegiance to, have access to and participate in specific practices that lead to
the formation o f a group with recognisable common bonds).
Gee’s description o f identity depends very much on the interpretation o f an
individual by others. Gee does acknowledge that we may have a ‘core identity’
but does not discuss how this could be integrated with the notion o f ‘how others
see us’. His theory relies on others having the knowledge to see you as a certain
type o f person but how this knowledge is developed within a historical context,
an institution, in discourse or by an affinity group is not discussed.
Combining aspects o f these two theories brings me to a working description o f
identity. I use ‘identity’ to mean the process o f coming to think we know who we
are, thinking we know who others are, them thinking they know who we are, us
thinking we know who they think we are and so on. This is not something we
have but something we work towards throughout our lives. We work towards our
identity (through doing identification8 work) by establishing and looking at the
signification between individuals, between collectives, and between individuals
and collectives and looking at relationships o f similarity and difference. Whilst
doing this identification work we view ourselves and others as certain kinds o f
8 Identification is the process o f coming to identity.
49
persons. We recognise ourselves and others to be a certain kind o f person within
a given context.
In the science identity literature described later in this chapter, as I stated above,
a range o f descriptions o f identity are used. One body of work that I have not
drawn on is that using a model o f science identity initially proposed by Carlone
and Johnson (2007). Although they use Gee’s ideas about the kind o f person you
are to underpin their proposed model o f science identity, Carlone and Johnson
(2007) go on to describe science identity as something that you have. This model
and modifications o f it have been used by Johnson et al. (2011) to study science
identity with women o f colour; by Carlone et al. (2011) and Carlone (2012) to
study the normative scientific practices o f a US fourth grade science classroom;
by Kane (2012a and 2012b) working with third grade African American
children; and by Hazari et al. (2010) to quantify the physics identity o f US high
school pupils. Whilst I acknowledge that some o f the outcomes from this
approach could inform us about what can influence a person’s developing
identification with science and physics, similarly to the research described in
Chapter 2, it cannot inform us what a science identity is if we understand identity
as something that we work towards, not something that is fixed and that we have.
Communities of Practice
Lave and Wenger explain that the concept o f community is crucial to their theory
o f situated learning (1991). They say
a community o f practice is a set o f relations among persons, activity, and
world, over time and in relation with other tangential and overlapping
communities o f practice. (p98)
Drawing on their perspective would involve the science classroom being viewed
as a community o f practice and learning in that classroom being viewed as an
activity where new members are inducted into that community o f practice. Lave
50
and Wenger explain that when a newcomer enters a community o f practice they
start from a position o f legitimate peripherality. This involves participation as a
way of learning the practices involved in that community. Continuing
involvement provides an opportunity for the learner to make the culture of
practice in that community theirs. The newcomer can then move towards
membership o f the community where its members participate at multiple levels
due to their different interests, diverse contributions and varied views o f the
community.
Communities of practice in science education literature
The communities o f practice framework has been used extensively in the science
identity literature (for example Brickhouse, Lowery and Shultz, 2000;
Brickhouse and Potter, 2001; Tan and Calabrese Barton, 2007, 2008; Danielsson,
2012), which will be discussed below. Much o f this work on science identity was
carried out in the USA in both middle and high schools (Brickhouse, Lowery and
Shultz, 2000; Brickhouse and Potter, 2001; Olitsky, 2006). These schools were
mainly in urban, poor areas with a high percentage o f African American and
Hispanic students.
Brickhouse, Lowery and Shultz (2000) investigated ‘What kind o f girl does
science?’ They followed twelve 7 grade girls at a US East Coast Middle School
over 18 months. Their study was ethnographic in nature (classroom observation
and interviews) and also included asking the girls to keep journals. They found
that one o f the issues with science education is that teachers are trying to
enculture students into what they believe is the science community o f practice
(namely research scientists) but that this is too far distant from the majority o f
students’ understanding o f what being a scientist is. They found that girls who
more closely conformed to their view o f scientists were responded to more
positively by the teacher. The two girls from this research who were identified as
fitting this pattern were one who was a good student overall academically but
who was not particularly interested in science (i.e. an “academic”) and one who
51
was only an average student academically but who used her social skills to
engage with the class. Girls who had a stronger identification with science as a
subject but who did not conform to what a teacher thought was a scientist were
not encouraged by the teacher. Two examples o f this type were one girl who
enjoyed figuring things out but was not “academic” and one who was loud in
class.
Brickhouse and Potter (2001) carried out a longitudinal, ethnographically based,
study o f ethnic minority girls in an urban setting. They collected data over threet l iyears, starting in the 7 grade. They found that girls in their study experienced
both marginalisation and participation in school communities o f science
depending on their social and personal identities (i.e. their gender, ethnicity,
socio-economic background, peer relationships). This is an example o f how the
various communities that are found in a school interact and how individuals may
be constrained by structure and power that limit the communities o f which they
can be part.
Olitsky (2006) investigated how discourse is part o f a community o f practice and
how the discourse used in the science classroom can also influence the
development o f a student’s identity. The commonly held discourse that portrays
science as ‘too hard’ conveys the idea that only a special type of person can have
an identification with science. The discourse in a science classroom however is
not the only discourse that contributes to identity formation. It is also the
discourses used by peer groups, the school system, the neighbourhood in which
students live and, o f course, the teachers. Olitsky’s research was part o f a study
of five schools in Philadelphia looking at science education in an urban setting.
She carried out classroom observations, student interviews and used students as
researchers. She found that students here were more likely to identify with
science if they were part o f the social groupings that were college bound or had a
social background (for example, higher socio economic level or parents who
were scientists) where they were more familiar with the language o f science.
This evidence suggests that again it is the social and personal identities o f
students that have strong influences on the development o f science identities.
52
How identities and participation in communities o f practice can be used to
explain persistence or not in the ‘science pipeline’9 was described by
Aschbachter, Li and Roth (2010). Using a sample o f 33 high school students,
who in the tenth grade all expressed an interest in pursuing a STEM course or
career, they explored why some, by the time they reached the twelfth grade,
persisted in this and why others changed their minds. They identified three
groups who they termed Lost Potentials, High Achieving Persisters and Low
Achieving Persisters.
Twenty five o f the students were described as Lost Potentials. These were
students who described a poor experience o f science at school due to poor
instruction and a lacklustre curriculum. They now found science hard and
described it as only for certain people. They now thought that science careers
were difficult to attain and more effort was needed to be successful in these types
of career. These students now found other subjects more interesting than science.
They also reported that their families’ encouragement to engage with science had
changed to being more negative. The remaining eighteen o f the students could be
termed as Persistors, but they could be split into two groups: twelve were further
described as High Achievers and six as Low Achievers. The High Achieving
Persistors were students who gained good grades in science classes, aspired to
‘high ranking’ professions and acknowledged that science could be hard, boring
and time consuming even though they wanted to continue to study it. The Low
Achieving Persistors demonstrated a disconnect between their aspirations and
levels o f science attainment but were still interested in choosing science careers.
They described more negative school experiences o f science. In general, they
came from lower class families, with fewer family members as science role
models and received less science specific support than their High Achieving
Persistor peers.
Members o f these different groups experienced different interactions with the
science communities o f practice both in and outside school and within the
extended family. The groups each experienced different micro climates within
9 See Chapter 2
53
each o f these communities o f practice. Students who found support for science in
multiple communities were more likely to consolidate their identification with
science and persist in their STEM aspirations that those who did not. These were
those students described as the High Achieving Persistors. Lost Potential
students found little or no support for their developing science identities in the
communities they were members o f and so left the science pipeline.
Danielsson (2012) used communities o f practice to investigate women university
students who were studying physics in a Swedish university. As she says, ‘the
voices o f women who have chosen to study physics are seldom heard’ (p25).
Using evidence from semi-structured interviews with five women, she identified
three typical ways that women interacted with the physicist community o f
practice. Firstly there were two women for whom the relationship between
gender and participation in the physicist community was central. One woman felt
that she was a non-participant in traditional femininity and that was how she
could be part o f this community whereas the other did not see herself as being
fully part o f the community and due to her gender played a more passive role in
the community. Two women felt that gender was not an issue with being a
member o f the physicist community as physics was gender neutral. Their
participation in the community was due to the work they had done to achieve
qualifications and autonomy in the laboratory. Finally one woman did not see
herself as a traditional physicist but as an experimental physicist who enjoyed
‘playing around with equipment until it worked’ (p35).
In summary, the outcomes from science identity research using communities o f
practice as the theoretical framework to understand identity has shown that there
is a cultural view, repeated by teachers in the classroom, o f who makes a good
scientist. This is someone who is typically described as a ‘good student’, but is
not necessarily one who has an identification with science as a subject. The
discourse used in the science classroom as well as the gender, the ethnicity and
the socio economic background o f the students are all found to impact on their
developing science identities. Students in the ‘science pipeline’ could be
described as either Persistors or Lost Potentials depending on how they
participated with the science community o f practice. Women who had already
54
chosen to study physics at university could also be described as being members
o f one o f three types, again depending on how they interacted with the science
community o f practice.
Criticisms of communities of practice theory
One o f the criticisms o f the use o f communities o f practice in education is the
question: what community o f practice are the students entering? Lave and
Wenger (1991) themselves discuss this.
For example, in most high schools there is a group o f students engaged
over a substantial period o f time in learning physics. What community o f
practice is in the process o f reproduction? Possibly the students
participate only in the reproduction o f high school itself. But assuming
that the practice o f physics is also being reproduced in some form, there
are vast differences between the ways high school physics students
participate in and give meaning to their activity and the way professional
physicists do. The actual reproducing community o f practice, within
which school children learn about physics, is not the community o f
physicists but the community o f schooled adults. (p99)
We need to be aware o f what we are trying to achieve in a school physics
classroom. From my own experience o f teaching chemistry, I would agree with
Lave and Wenger that we are not introducing students to the community o f
practice o f professional chemists (either industrial or academic). We are
introducing students to an understanding o f the subject. This may in future
encourage some o f them to move into the community o f the chemist; or to use
their knowledge o f chemistry to embrace other scientific communities o f
practice; or to become a member o f the scientifically literate community who do
not further their study o f chemistry but understand the importance o f it.
55
The issue o f the use o f communities o f practice to describe mathematics
classrooms was discussed by Boylan (2010). In communities o f practice,
newcomers participate from a legitimate peripheral position until they become
members o f the community. They learn about the community from old timers.
However, learning in a school classroom is modelled as individual acquisition o f
knowledge rather that social participation and this learning is frequently not
contextualised. In the, often, transmissive pedagogy that is found in school
classrooms, teachers and students do not learn along side each other. The teacher
is expected to ‘already have the knowledge’ (p i0). Also, the teachers are not
teaching the students to become the same as them (teachers) as would be the case
in apprentice learning that forms the examples used in communities o f practice
theory.
My working theory of identity, based on Jenkins and Gee, is a process whereby
we come to think we know who we are as we, and others, come to see ourselves
as a certain kind o f person. We develop within many communities o f practice but
the majority o f them do not operate where we engage with them as apprentices in
order to become old timers. I needed a different way of describing the places
where our identities develop. In science identity literature, the use o f figured
worlds has come to the fore, and I looked there for an alternative.
Figured worlds (Holland et al., 1998) offer a more flexible way o f describing the
various socially constructed collectives that we live in than communities o f
practice, and so I feel that they describe the places where our identities develop,
and the spaces that are available for identity development in a classroom, in a
more understandable way. Figured worlds are like communities o f practice in
that they do have a historical dimension, they do have social postionality where
participants’ positions matter, they are socially organised and they do develop
over time; but they are not primarily focused on experts introducing new
members into the workings o f that community. This offers a different way to
look at the physics classroom, one that will be described below.
56
Figured Worlds
Holland et al. (1998) describe identity as a combination o f the personal world
with the collective/social world; as a social product; as living in and developing
in social practice; and as developing over a lifetime (p5). Their ideas o f identity
are based on work by Vygotsky and Bakhtin who view humans as social and
cultural creatures who can move to form a set o f socially and culturally formed
subjectives by using human agency. Holland et al. develop these ideas to focus
on the development o f identity and agency specific to practice and activities in
‘worlds’. Holland et al. call these worlds ‘figured worlds’. The theoretical
background o f figured worlds is that they are a historical phenomenon; they are
social encounters where participants’ positions matter; they are socially
organised and reproduced; and distribute ‘us’ across different fields o f activity
(p41).
The formation o f figured worlds rests upon our ability to form worlds and be
formed in collectively realised ‘as i f realms. These worlds take shape and grant
shape to the co-production o f activities, discourses, performances and artefacts.
Within these figured worlds are figures, characters and types who carry out its
tasks, interact with it and each other and develop it. For figured worlds to exist
they need to be both socially generated and culturally constructed. We can
recognise figured worlds because we recognise particular characters, acts and
worlds as being part o f a given world. People within these worlds recognise
particular outcomes over others. These worlds are formed and re-formed in
relation to their participants’ everyday needs. An example would be that we, and
students, can describe and reproduce a ‘normal physics classroom’.
For Holland et al. identities are formed in the process o f participating in the
activities that are organised by figured worlds. When we interact with a figured
world it can be at many different levels; from fully embracing the world, to
rejecting the world, to many different degrees o f interaction with the world.
Whatever level o f engagement we end up having with a particular world, our
identity is affected by it. In our everyday life we will encounter many different
57
figured worlds; those that we fully engage with, those that we reject and those
where we are still developing our identities.
Figured worlds in science education literature
Tan and Calabrese Barton (2007, 2008, 2009a and 2009b) use both communities
o f practice and figured worlds to describe their findings. They say that
communities o f practice can be thought o f as figured worlds and that the
classroom is a community o f practice so therefore a figured world. However,
they do not discuss any differences between how communities o f practice or
figured worlds are established.
Tan and Calabrese Barton studied girls in a US Middle School. They carried out
an ethnographic study o f a grade 6 science class which included thrice weekly
lesson observations, two individual and group interviews, informal conversations
and observation o f student work. They reported on three cases in particular in
their first two papers and the classroom overall in their 2009 papers. One case
outlined a girl who moved from being a non participator in the class to being a
key member o f the class. This was seen as an example o f how fluid student
identities can be. Identity is not single. A person can experience many different
identities depending on which communities or figured worlds they inhabit. These
multiple identities are often hierarchically valued or positioned through peer
relationships and societal structures. This girl exhibited personal agency in
authoring her identity (i.e. she changed/re-wrote in her own words her identity to
fit the new community/figured world she wanted to inhabit). To modify her
identity she was both empowered and supported by her peers and her teacher.
The other two case studies illustrated how two other girls authored new and non-
traditional science learner identities that merged their life worlds with the world
of school science (two different communities/figured worlds). Again these girls
demonstrated a strong sense o f agency through authoring o f these novel
identities.
58
The 2009a paper discussed how the classroom itself consisted o f three emergent
figured worlds - that o f a storytelling world, that o f being a ‘real’ world and one
that allowed diverse, authentic, science-based participation. The storytelling
world involved the students telling stories about how they experienced science in
their home, whilst travelling and in their neighbourhood. The figured world o f
being real utilised the students’ ‘youth-based reality’ which was comprised o f
the discourses and practices that dominated the students’ out o f school
experiences. The third world, that o f a diverse, authentic, science-based
participation, was where the students took up roles other than that o f a traditional
student (for example, pet caretakers, plant caretakers and student leaders). This
allowed all students, even the less prominent ones, to gain ownership, authority
and agency in science. These figured worlds were not distinct but diverse and
shifting. The students within the class engaged differently with each figured
world and their science identities also developed differently in each figured
world.
Calabrese Barton and Tan (2010) also looked at science learning in informal,
inner city, after school science clubs. These clubs encouraged learners to
embrace the figured world o f science by developing their locally instanced sense
o f agency. The students here actively engaged with the out o f school activities
that allowed them to develop an identity not usually available to them within the
school setting.
Out o f school science clubs have also been a focus o f research by Rahm (2007)
and Rahm and Gonsalves (2012) to investigate how students’ science identities
develop within a figured world o f science and scientists that does not have the
constraint o f being seen as ‘typical school science’. Rahm describes how at the
start o f a summer science club most students described scientists using the
typical stereotypes described in Chapter 2. They could not see themselves as part
o f this figured world o f scientists as it was too different from how they saw
themselves. After meeting and interviewing practising scientists, the students
came to see them as ‘being human’ and reported that the figured world of
scientists was not as far from their views o f themselves as it had been originally.
Rahm and Gonsalves reported that, when girls first encountered the after school
59
science club, the figured world o f normative science (i.e. one that is authoritative,
incontestable and where girls don’t do it) is reproduced. However, as the girls
engaged with the programme, they came to construct temporary science
identities and become partial insiders o f the world.
Most young people learn about science within the figured world o f school
science. Within a school there will be the figured worlds o f the different school
subjects as well as the figured world o f the school as a whole into which pupils
bring their social worlds from outside school. The figured worlds o f the school
classrooms are systems o f social activity that are governed by the norms (for
example, the patterns o f interaction, values, actions, behaviours expected) o f that
classroom. Within these figured worlds, the pupils see and position themselves as
different kinds o f people. Varelas et al. (2011) reported on three classrooms (one
first grade, one second grade and one third grade) in an urban, economically
struggling area o f the US. Even at this young age, pupils saw themselves as
‘doing science’ and/or ‘doing school’ within a science classroom. How the pupils
saw themselves within science and how they saw science overall was shaped by
the ways they saw competence in the classroom and by the feedback given by the
teacher. Competence in science was perceived by pupils as those who could
build, design, observe, figure it out, get it right and discover and competence in
the classroom was seen as working hard, helping others, respecting the teacher,
learning lots o f information, doing well in tests and working for higher grades.
Those pupils who saw themselves as scientists within this world felt that it gave
them status, made them feel good and allowed them access to further knowledge
and education.
The links between school and science and the roles available to young people
within a science classroom were investigated by Shanahan and Nieswandt
(2010). They found that students had a clear view o f what the typical science
student’s role was within a science classroom, within the figured world o f
normative science classrooms. Science students were expected to be intelligent,
demonstrate scientific actions and attributes, exhibit scientific skills and display
overall good behaviour. These attributes were consistently identified by both
male and female students and by science teachers.
60
Price and McNeill (2013) have recently looked at how using a different science
curriculum can foster links between the different figured worlds that school
pupils inhabit. Working in the US with a high school ecology curriculum they
found that the science curriculum could serve as a pivot between the world o f the
scientist, the world o f the educator and the world of the student. Even though
each o f these participants brought different meanings to the curriculum, there
were opportunities developed where the different figured worlds could intersect.
Influences o f the teachers on the figured world o f science were investigated by
Gilmartin et al. (2007). They found that amongst 1138 10th grade students in five
Southern Californian schools the percentage o f female science teachers had no
effect on emerging science identities. Students were much more likely to respond
positively to teachers who were caring, challenging, engaging, passionate about
their subject, fair and who made links to actual science regardless o f their gender.
Investigating the different figured worlds o f classrooms has also been used in
mathematics education by Boaler and Greeno (2002). They carried out 48
interviews with high school students from six schools. They found that within
these schools there were two distinctive figured worlds o f mathematics
classrooms - those that used traditional didactic teaching methods and those that
used a discussion based teaching model. Within these two figured worlds
students positioned themselves differently. Within the didactic classrooms the
students’ roles were narrowly defined; they were required to find the one correct
answer, to think o f mathematics as a closed, rule bound subject and to be passive
receivers o f knowledge. Within the discussion based classroom the students were
engaged in negotiation and interpretation and were more active learners. Boaler
and Greeno found that many able mathematics students did not want to author an
identity that was part o f the didactic classroom figured world; the students did
not want to author an identity as passive receivers o f knowledge. Within the
wider figured world o f the school, students moved between the different figured
worlds o f the individual subject classrooms and authored different identities. The
choice as to whether to continue to study mathematics was a part o f the identity
formed within the mathematics classroom’s figured world that the students
encountered.
61
As mentioned above, it is not just the figured worlds o f the individual subject
classrooms that students encounter at school but the figured world o f the school
as a whole. The figured world o f the whole school has discourses, practices,
categories and interactions that can shape learner identities. Rubin (2007)
investigated a US school where its students were classified as urban and
deficient, used pedagogical practices that focused on rote learning and negated
inquiry and saw humiliation as an acceptable form o f interaction. For students
who did not want to see themselves as this type of learner they found life at
school to be very difficult. They did not fit into this figured world and could not
develop meaningful identities as learners within it. Freire et al. (2009) working in
Portugal with ‘at risk’ students found that many o f these students wanted to
succeed at school but that the figured world of school did not allow them to
pursue their own path towards this goal. If they did not conform to the expected
norms o f the figured world and take up the positions available there, and given to
them by teachers, they found themselves on the edge o f the world and unable to
engage fully with it, so leading to school exclusion.
As with Danielsson (2012) who used communities o f practice to look at
undergraduate physics students, Gonsalves and Seiler (2012) used figured worlds
to look at the worlds o f physics doctoral students. They found that the figured
world o f physicists resounded with the discourse o f recognisable physics (i.e.
stereotypical physics as described in Chapter 2). Women within this world had to
decide whether to conform to the stereotypes offered to them or not. They found
that for many women, being recognised as a physicist was the key component to
their engagement with the figured world. To inhabit this world, the women had
to perform, in varying degrees, stereotypical physicist attributes and recognisable
physicist attributes.
As identity is being worked on within the figured worlds that students encounter,
it can be thought that this identity work is being done along an identity trajectory.
The concept o f identity trajectories was first proposed by Wenger (1998) who
said that identity was not a static phenomenon but was one that moved along a
trajectory; identity is in constant motion. Calabrese Barton et al. (2013) used the
concept o f identity trajectories within figured worlds to describe the identity
62
work carried out by two African American girls who they followed over three
years during their middle school careers. They described the science classrooms
where these girls learnt science as being comprised of a complex web of many
figured worlds. For example they observed two worlds frequently; that o f whole
group activities and small group interactions. Both o f these worlds have
historical and cultural norms that describe participation and what it means to be a
‘good student’. The pupils in the class were involved in the process o f authoring
and reauthoring themselves through participation in and resistance to the
practices of these figured worlds (illustrated in figure 3.1).
Figured worlds that bear system s o f activities
Figured world
Identity work takes place at^rarticular
time apd place (focal / event)________
Future sense o f self(s)
H ybrid space, blurred area among different spaces, having modified activity systems with the expansiono f resources & newly T im elegitimatized roles, norms as the result o f merging
iffcrent spaces
Science club
Future sel/(s) in science
School science
Figure 3-1 Configuring identity trajectories (p66)
The two cases describe two different identity trajectories. Firstly there was Diane
who was described as having ‘complex contradictions’. She saw science as a way
o f understanding the world and a tool for solving problems but never identified
herself as being ‘good at science’. Fter identity work lost momentum as she had
to choose between competing memberships o f differed figured worlds that she
had compartmentalised. In contrast to Diane was the trajectory of Chantelle
63
whose identity work towards science gained momentum across the many figured
worlds she encountered both within science classes and at a science after school
club. At the science after school club she found she could use dance and acting to
explain scientific concepts to others so found many figured worlds came
together; she did not have to choose between them as Diane felt she did. These
girls made very definite shifts in their science identity trajectories when they
either came to see themselves in respect to science in a different way or
perceived that others viewed them in a different way. These shifts were made as
a result o f either finding new meanings in their relationship with science or by
coming up against closed and inflexible structures that did not align with their
science practice.
The concept o f identity trajectories, explained above, was also used by Jackson
and Seiler (2013) to describe how late comers to science identified with the
figured world. They classified these students as having one o f three overall
science identity trajectories (or combinations o f the three) over the time that they
were enrolled in a ‘catch up’ science programme at a Canadian college. These
three trajectories were:
a/ inbound - an increasing identification with science
b/ outbound - a decreasing identification with science
c/ peripheral - identification near the dividing line between identification
and dis-identification.
These overall trajectories were not constant but a Tine o f best fit’ through the
fluctuating identities at any moment in time (see figure 3.2).
64
Figure 3-2 Representations o f four o f the many possible science identity trajectories a hypothetical latecomer to science may construct during her first year in CEGEP science. (Zero on the identification axis represents the dividing line between identification with, or motion towards science, and dis- identification with, or motion away from science. The magnified view illustrates a finer time scale and shows the curve o f best fit drawn through the scatterplot o f points representing motion relative to science. Although shown for only one trajectory, it highlights that all trajectories entail shifts and variation in identification over time.) (p830)
Jackson and Seiler found that the identities o f the students they investigated were
often shaped by the constraints o f the cultural models within the figured world o f
the college science programme. The figured world o f the science programme was
embedded within the wider figured worlds o f science and education and these
wider figured worlds contributed to the resources available to the students and
therefore impacted on their trajectories. However, the figured world o f school
science does have its own distinct historic and cultural norms that ultimately
describe what it is to be, and to be seen as, a successful science student. It is this
combination o f factors from both the school science world and the wider worlds
it sits within that often provoke or nurture critical shifts in trajectory, for example
from an inbound to an outbound trajectory. In order to persist in the programme
(have an inbound trajectory), students needed to improvise in order to maintain
their identity trajectory and a thickening o f their identity was related to the
accumulation o f resources to help them be successful on the programme.
65
The outcomes from the research using figured worlds as the theoretical
framework in which identity development takes place are similar to those where
communities o f practice are used. However, as described above, the figured
world theory allows for a more flexible way to study the way learning takes place
in both classroom spaces and all the rest o f the spaces that make up a young
person’s world. Many science classrooms, and to some extent outside school
science learning spaces, present a figured world o f ‘normative science’ and this
can mean that students participate in it to differing levels over time. As different
figured worlds emerge in these spaces, students can develop different identities.
An issue here is whether these different figured worlds, and the identities that are
developing there, are mutually exclusive or overlapping. As the student’s identity
develops, it follows a path; an identity trajectory.
Communities of Practice or Figured Worlds?
As outlined in the previous sections, both communities o f practice and figured
worlds have previously been used to provide a theoretical framework when
researching the development o f science and physics identities. These theoretical
frameworks have been used both separately (e.g. Brickhouse, Lowery and Shultz,
2000) and together (e.g. Tan and Calabrese Barton, 2007) to describe science
identities with no effort, when they are used together, to distinguish between
them. Communities o f practice have been described as figured worlds and vice
versa. In this section, I start the discussion about some o f the differences between
communities o f practice and figured worlds, and why I used figured worlds to
analyse my data.
Over the years since Lave and Wenger first proposed their communities o f
practice theory (1991), the theory has been developed (Wenger, 1998) and it has
been used to describe a variety o f situations. My arguments are based on the
original 1991 theory. Here, participation in a community o f practice, and so
developing an identity within that community o f practice, is based on legitimate
peripheral participation. Newcomers to a community o f practice observe the
66
practices o f old times who in turn teach the new comers the practices o f that
community. Over time, the new comers, through practice, themselves become
old timers. The physics classroom, however, is not a place where physicists are
teaching and introducing new comers into the community o f professional
physics. Physics teachers are instructing their students on the principles o f
physics to meet the requirements o f the National Curriculum and in the hope that
some o f the students will be inspired to study physics further. Learning in a
physics classroom is based on a student acquiring knowledge individually not as
part o f a social practice within a contextualised community.
Participation in a figured world can be more varied and can take many forms,
including disaffection. Participation in a figured world can be at many different
levels and is dependent on how much the figured world becomes part o f the
overall identity o f each participant. Participation in figured worlds is not based
on new comers being shown the ways by old timers. In one o f the examples used
by Holland et al. (1998), that o f the world o f romance, participants are assumed
to have knowledge o f what the world is and they then choose how much they
wish to be part o f that world. This is similar to what has been described as ‘usual
school physics’. This figured world has both a historic and social context.
Participants know what the world o f ‘usual school physics’ looks like without
having to be introduced to it by old timers. This figured world can be shaped and
re-shaped by participants as they find their position in that world.
The freedom to find a place within the figured world o f the physics classroom, as
impacted on by other figured worlds, is due to the dialogic nature o f identity.
This allows individuals to develop an identity that is composed o f a number o f
different views simultaneously regardless o f any tensions or logical compatibility
between them. The historical nature of the figured world allows participants to
develop a history o f person (Holland and Lave, 2009). Further, one’s identities,
once they have become formed in history in person, provide a ground for agency
whereby each individual can improvise their behaviours to form an identity that
clearly reflects their position within that world. Communities o f practice do not
allow such freedom as agency to shape the community only comes about once
full participation is achieved.
67
The physics classroom can be thought o f as a figured world in its own right but
other figured worlds impact on it and can influence how much a girl engages
with it. These other figured worlds can include that o f a conscientious student,
that o f a school ethos o f hard work and striving for achievement, that o f a social
place amongst peers, that o f family, that o f how society in general perceives girls
who engage with physics; or more generally, the life world o f that individual. An
individual has the power to find their own place in each o f these worlds but
within the constraints o f that place being recognisable to others, a component
part o f identity development.
Self Efficacy
In the introduction to this chapter, I described that originally my intention was to
investigate the two topics o f identity and self efficacy as separate entities, as had
been done previously. Studying the literature o f both identity and self efficacy
showed how closely these two were related to each other. For example, in their
discussion o f how the Eccels et al. (1983) model o f choice can be used in the
Scandinavian tradition o f linking choice to identity (see Chapter 2), Boe et al.
(2011) discuss how identity forms expectation and values and thus affects
achievement related choices. They then go on to describe how components o f the
model relate to both identity and self efficacy. This section on self efficacy starts
with a definition o f self efficacy before linking it to identity and briefly
reviewing some o f the self efficacy literature that can add to our understanding o f
identity.
Self efficacy is a psychological quality which Bandura (1982) defined as ‘one’s
perceived capabilities for learning or performing actions at designated levels’
(pi 22). He argues that self efficacy is not a fixed act or simply a matter o f
knowing what to do. Self efficacy is concerned with a person’s judgment o f how
well they can execute courses o f action to deal with situations. In order to do this,
cognitive, social and behaviour skills must be organised into a course o f action.
68
This definition suggests self efficacy forms a part o f one’s identity. If identity
can be thought o f as how we work towards the process o f coming to think we
know who we are within a figured world then our perceived capability o f
learning or performing within that figured world, our self efficacy, must form
part o f our identity. This is further confirmed by Bandura’s classification o f four
causal factors that affect a person’s level o f self efficacy as they can also be seen
as factors that influence our identity.
Bandura’s four causal factors for affecting the level o f self efficacy are:
1. mastery experience
2. vicarious experience
3. social persuasion
4. physiological states.
Mastery experience deals with previous performances o f tasks. Experiences that
have previously been successful generally raise a person’s self efficacy whereas
failures lower it. Self efficacy can be most affected by successes that have
resulted from overcoming challenges. Vicarious experiences arise from seeing
similar others perform a task. This is based on ‘if they can do it, I can too’. The
more similar in nature the ‘other’ is to the observer, the greater the influence on
their self efficacy. Social persuasion is the exposure to both verbal and nonverbal
judgements or feedback on previous experiences. When giving feedback, it is
much easier to weaken self efficacy through negative comments than it is to raise
it through positive feedback. The final factor that can affect self efficacy is
physiological states, for example, anxiety, stress, mood states. How these affect
self efficacy is based on how much belief a person places in these as indicators o f
success or failure.
Reading the literature about self efficacy in science, physics and mathematics
also brings to the fore another issue: the interchangeable use o f different terms to
define the same or very similar qualities. Within this research the terms self
efficacy, self concept, self perception and self belief are all used, often
69
interchangeably10. This brief review focuses on self efficacy research that, if we
think o f this as part o f our identity, can add to our understanding o f how identity
develops and is influenced within the figured worlds that we encounter.
Studies of self efficacy
A review o f self efficacy development in adolescents was carried out by Schunk
and Meece (2005). They looked in detail at how adolescents’ self efficacy
developed using the four sources identified by Bandura. They found that school
influences, families and the home environment and peers had significant effects
on self efficacy. The school influences included how teaching was structured, the
ease or difficulty o f learning, how teachers gave feedback on performance and
graded work and how much and the type o f attention given to pupils by the
teacher. They found that classrooms where the emphasis was on competition and
performance goals led to a decline in self efficacy. Self efficacy increased in
classrooms where the emphasis was on the importance o f effort, meaningful
learning, self improvement and collaboration and where student interests were
taken into consideration in the learning contexts used. Self efficacy was higher in
adolescents where the family provided an environment that encouraged them, set
high but realistic aspirations, contained positive role models and provided
support for mastery experiences. Adolescents were found to be greatly
influenced by their peers. Their self efficacy could be raised by observing peers
accomplishing tasks, especially those from their own, self selected, peer group -
that is those peers with similar levels o f attainment and interests.
Self efficacy has been found to be a strong predictor o f academic achievement,
course selection and career decisions (Britner and Pajares, 2006). Britner and
Pajares carried out a quantitative investigation into science self efficacy and self
concept beliefs in 319 (155 boys and 164 girls) US middle school students. The
survey included questions asking the students to give opinions, using a Likert
scale, on science self efficacy (for example: I got a good grade in science last
10 In the discussion of the literature, when discussing particular texts, I use the term used by the authors. In my own discussions, I use self efficacy.
70
semester, My teachers believe I can do well in difficult science courses); on their
science self concept (for example: Science is easy for me); on their science
anxiety (for example: Science makes me feel uneasy and confused); on their
general self efficacy for learning (for example: How well can you finish your
homework on time?); and to report their science achievement. Britner and
Pajares found that mastery experience had the greatest influence on self efficacy.
They also found that the differences between genders was minimal, although
girls reported a slightly higher anxiety about performance in class and more
confidence in their ability to manage studies whereas boys reported a slighter
higher self concept in science . It is interesting that they found little difference
between the genders, as previous studies (Heller and Ziegle, 1996; Meece and
Jones, 1996) had found that females tended to have a lower self efficacy in
science than males.
Specific examples o f research into self efficacy/concept in physics are limited.
Haussler and Hoffmann (2002), in Germany, carried out a classroom intervention
study to see if they could enhance girls' self concept o f physics. The intervention
took a whole school year o f some 60 one hour lessons and comprised 12
experimental and 7 control classes o f 13 year old pupils. Their physics related
self concept, as well as achievement and overall interest in physics, were
assessed by written tests at various stages o f the intervention. Overall, they found
that several changes (for example, adapting a curriculum to account for the
interest o f girls and using gender fair teaching) could be made in the classroom to
enhance girls' interest, self concept and achievement in physics.
Self efficacy and learning content in a Chinese physics classroom was also the
subject o f a paper by Zhu (2007). She reflected that when she herself was
learning physics in China she did not learn well in junior high school. This she
felt was not due to a lack o f ability but that the physics she was learning did not
make sense to her and also to many o f her female classmates. This, she felt, was
due to the lack o f variety in the physics teaching and a boring text book. She had
a better experience at senior high school, where, although the physics content
became more abstract, the teacher used more meaningful activities to explain
concepts and also used more collaborative activities. When she became a physics
71
teacher herself she tried to use ICT to give examples o f physics phenomena and
to make physics learning fun and relaxing. She concludes by saying that there is
a relationship between the learning content o f physics curricula and physics self
efficacy and, to some extent, girls’ development o f gender identity.
A quantitative study o f the relationship between self efficacy and retention in an
introductory physics course at a US college was carried out by Sawtelle, Brewe
and Kramer (2012). They surveyed 352 students both pre and post course. They
found that for women, their self efficacy was greatly affected by vicarious
sources; that o f seeing similar others being successful in a given task or
assignment.
To summarise, it has been found that the school, particularly teachers and
teaching, the family and peers can all influence the level o f a person’s self
efficacy. Poor support from all o f these groups led to a decrease in self efficacy.
The literature discussed in Chapter 2 looking at subject choices and the reasons
for those choices also showed that students were less likely to choose a subject if
they did not have the support o f their family and friends and if they encountered
poor teachers and teaching in those subjects. Self efficacy has also been found to
be a good predicator o f future course and career selection. The lower the reported
self efficacy for a subject, the less likely a person is to choose that subject for
future study.
Identity, Self Efficacy and Narrative
In this section I focus on literature using narrative to investigate identity.
Narrative is an essential part o f investigation o f figured worlds; the stories we tell
about how our identities developed within a figured ‘as i f world. Some o f the
papers already discussed in the section about science education and figured
world used narrative as one o f their research methods (Johnson et al., 2011;
Gonsalves and Seiler, 2012;Kane, 2012a and 2012b; and Guerra et al., 2012).
72
The work discussed below does not use figured worlds as a theoretical
framework but does use narrative.
Sfard and Prusak (2005) used narratives to investigate identity. In order to do this
they offered a new definition o f identity as collections o f stories about persons,
or those narratives about individuals that are reifying (real to them), endorsable
(supported) and significant (caused a change). With this narrative definition of
identity the dynamic nature o f identity is brought to the fore. Narratives will
always have authors and recipients (although they can be the same person), are
collectively shaped and can change according to the authors’ and recipients’
perceptions and needs. Identities can be therefore be seen as either actual or
designated. Actual identities are those stories about the actual state o f affairs and
designated identities are stories about what is expected to be the case. They
propose that learning can therefore be thought o f as closing the gap between
actual and designated identities.
This definition o f identity, that we have both actual and designated identities,
was also used by Tucker-Raymond et al. (2012) in their work with 54 first,
second and third grade children. They asked these children to draw images o f
themselves and science and then talk about them both before, during and after
they had studied a year’s science course. They found that the pictures and the
stories attached to them changed as the pupils’ identification with science
developed during the year.
A combination o f Gee’s description o f identity as the kind o f person we are and
Sfard and Prusak’s actual and designated identities was used by Pike and Dunne
(2011) to discuss their findings on students’ post-16 choices. Their three
identified factors (school pedagogies, discourse o f difficulty and future careers)
all had a major influence on the students’ learner identities, their identification
with science and their choice as to whether to study science post-16 or not (see
Chapter 2).
The ASPIRES project in the UK has looked at how primary school children
engage with school science and explored their attitudes toward science and
73
interest in science. Some o f their findings have been discussed in chapter two
(Archer et al., 2013 and De Witt et al., 2013). In a 2010 paper Archer et al.
looked at ‘doing science’ and ‘being a scientist’ using focus groups to gather data
and analysed the data using narratives and how the pupils formed an
identification with science. They found that many children enjoyed science but
did not see themselves as doing science because the image o f a scientist clashed
with their images o f themselves. Scientists were seen to fit the stereotypical
images discussed in chapter two.
Looking at discourse rather than narrative, Hughes (2001) looked at how
secondary pupils talk o f both the importance o f gender and ethnicity in the
production of, or rejection of, ‘scientist identities’. She found that hegemonic
masculinity provided a comfortable ‘scientist identity’ for some males, but that
for girls femininity and ‘physical scientist identities’ were incompatible unless
‘othered’ by ethnicity.
Working with the children o f migrant workers in the US, Kozoll and Osborne
(2003) told the stories o f four students; looking at their life worlds and the world
of science. These students all had a different relationship with science. There was
Hector who felt that his world and the world o f science were so different that
they would never connect; Clara whose identification with science changed when
she was allowed to use her creative side in science class; Andrea who saw
science as a place where she could be an insider; and finally Keith whose
understanding o f science allowed him to understand himself.
Walshaw (2005) also uses narrative to investigate one girl’s interaction with
mathematics within a school setting. The girl’s identification with mathematics is
complicated and influenced by past beliefs about girls and mathematics where
these beliefs are ‘not discarded but are simply shifted to, and contained within,
her present’ (p31). This narrative is also constructed in relation to significant
others in the girl’s life - her family, her teacher, her best friend and her
mathematics classroom peers. Overall the girl’s identification with mathematics
is ‘produced through a convergence o f a number o f often competing discourses
and practice, each vying for her attention, and all o f which position and designate
74
her in some way’ (p24). This has a direct parallel with identification with
physics, or any subject.
Narratives were also used by Mendick (2003) in her work on masculinities in
mathematics. She looked particularly at how mathematics became part o f a
gender identity and how young people worked at being male or female through
their identification with mathematics. Jenkins description o f identity as who we
think we are and who others think we are is o f particular relevance here as these
young people came to work on who they were in relationship to mathematics and
their overall gender identity and how the two worked together. Mendick also
describes how she sees that identity in general, and gender in particular, is a
project that is achieved by interaction with others - how they see us. For
mathematics, choosing to study it or not becomes part o f our work towards
identity and gender. The main discourses at play in this process for mathematics
are that mathematics is ‘hard’; that it is proof o f intelligence and a signifier o f
social incompetence. These discourses are gendered so that it makes it more
problematic for girls to identify with the subject and so make the decision to
choose to study it.
Using narratives to investigate identity development allows us to study the
stories people tell about how their identities develop from what Sfard and Prusak
(2005) term their actual (or now) identities to their designated (or how they see
themselves in the future) identities. These stories change as identity work takes
place. Influences discussed in these narratives as impacting on identity
development include the discourse o f science as hard; wanting to pursue a
fulfilling career; social perceptions o f the image o f science, physics and
scientists; and how the world o f science interacts with the wider world. These
influencers o f identity development are the same as those discussed in Chapter 2
when discussing the influencers o f subject choice.
These narrative accounts o f how young people do identity work seemed to me
both telling and powerful. I therefore was drawn to using a similar approach in
my analysis (see Chapter 4).
75
Summary
As can be seen from the above discussion o f the literature, a variety o f ways o f
using the concept o f identity has been applied in research on girls and science,
physics and mathematics. I started the chapter by developing my own working
description o f identity based on the work o f Jenkins (2009) and Gee (2001). This
is that we each have an individual identity where we work towards the process of
coming to think we know who we are, thinking we know who others are, them
thinking they know who we are, us thinking we know who they think we are and
so on. I also proposed that we work towards our identity in the many figured
worlds (Holland et al., 1998) that make up our society. It is in these figured
worlds that we come to recognise ourselves and others as certain types o f people.
Our identification with science and physics in particular is formed within those
figured worlds where we encounter physics; both those in a school classroom
and those outside. These figured worlds are part o f the wider figured world o f
our lives and the wider figured world o f our lives is composed o f many smaller
figured worlds. How we negotiate our identities within all these figured worlds
allows us to become to know who we are. Our relationship with physics, our
identification with physics including our associated physics self efficacy, is
dependent on how much the figured world o f physics plays a part o f our wider
figured world from a major part to only a minor part.
The research discussed in this chapter uses a variety o f ways o f understanding
identity and there are many points that will re-emerge and inform my analysis.
Using narrative to investigate identity, which Sfard and Prusak (2005) describe
as the process o f ‘collecting stories we tell about ourselves’ (p29), led them to
describing identities as actual (where we are now) and designated (where we
want to be). Collecting people’s stories also highlighted the links between gender
and ethnicity and science identity (Hughes, 2001). Girls often described that
femininity and physical science identities were incompatible unless they were
‘othered’ by ethnicity. Similar descriptions were found by Walshaw (2005) and
Mendick (2003) for mathematics where choosing to study mathematics became
part o f identify work and of gender work. That identity work includes issues o f
76
gender was also described by women already working in physics who found that
they often had to decide whether to conform to the expected stereotypical view
of being a physicist and how this impacted on their femininity and gender
identity (Danielsson, 2012 and Gonsalves and Seiler, 2012).
Looking at self efficacy showed the links between this and identity. Self efficacy
has been proposed as a predictor o f academic achievement and future subject
choice with the higher the self efficacy the higher the achievement and the more
likely someone is to choose to study that subject further (Britner and Parjares,
2006). Girls are generally found to have a lower self efficacy than boys (Meece
and Jones, 1996) especially in science subjects. Since choice is part o f identity
work, and self efficacy can predict choices, links between the two need to be
made.
How identity develops over time can be described as an identity trajectory
(Wenger, 1999). Our identification shifts at key points in time (Barton et al.,
2013) and can lead to three possible overall trajectories to describe our
relationship with science (Jackson and Seiler, 2013). Whether we choose to
persist in a study o f science or not led Aschbachter, Li and Roth(2010) to
categorise this persistence and relate this to our identity work.
As Aydeniz and Hodge (2011) say ‘identity is a complex structure for
researching a student’s academic behaviour’ (p500). As I explain in the chapter
which follows, this led me towards using interviews to find out how girls’
identification (and self efficacy) with physics developed. Taking this a step
further, narratives from individual girls were developed to give examples o f
identity work being undertaken with respect to physics.
77
Chapter 4 Methodology and Method
Introduction
This chapter outlines both the methodological thinking that went into the project
and the methods used to gather the data that is analysed in later chapters.
The research moved through three iterations o f methodological thinking and
these are described in detail in the chapter. The methods used, or proposed, for
data gathering in each iteration are also described.
Methodological Approach
Methodological thinking and the methods used to carry out research are
interlinked and there is often a cyclic process between the two. At the start o f a
research project much methodological thought is put into justifying why a certain
method or methods are chosen to investigate a topic. Whilst the research is
progressing the methods will be modified as problems and data emerge.
Methodology has been described as a combination o f epistemology, ontology
and method (Pawson, 1999). Traditionally, epistemology has been concerned
with what distinguishes different types o f knowledge claims (Usher, 1996).
Researchers will approach a project holding certain assumptions about what they
will find and how they will find it out (Creswell, 2003). Purists will say that
researchers have to work within just one paradigm, that paradigms are
incommensurable and there is no possible way that research carried out in
different paradigms can be compared (Coe, 2012). Some researchers hold to the
stance that paradigm differences do not require paradigm conflict and that,
depending on the question to be answered, different approaches are appropriate.
This is a stance I support and one that informed this research.
78
It is suggested (Guba, 1990) that there are twenty one different ways to define
paradigm. The most common, or generic, definition is that it is the basic set of
beliefs that guides action. Paradigms can guide disciplined enquiry. My
background is in physical sciences and the majority o f physical scientists work
within a positivist epistemology. The underlining principle o f positivism is the
use o f scientific method (the systematic observation, measurement and
experimentation needed to test and modify a hypothesis) to discover truths about
the world (Willis, 2007). Positivists believe that the events in the world follow a
lawful and orderly pattern that can be discovered by close observation; that
different observers will reach the same conclusions when looking at the same
data; and that when questions are put to nature, nature answers back directly. My
previous research into the mode o f action o f enzymes as a research chemist
would fall easily into a positivistic paradigm. In this research project, I wanted to
try and understand aspects o f the individual. In my view positivistic research is
not a route to understanding all aspects o f the individual and their identity.
Trying to understand the individual led me to post positivism.
The post positivist researcher is a ‘naive’ realist. They believe that the real world
is driven by real natural causes and it is possible for humans to perceive it. They
still believe that there is an ultimate truth out there even if they cannot uncover it.
These researchers therefore still carry out detailed observations and measurement
o f variables in order to test theories that are continually being refined. Findings
to support, or which lead to a modification of, the theory, emerge from the
interactions between the inquirer and the inquired. Each participant in the
research will give a range o f perspectives about the topic being studied. This
leads to the findings being based on many sources o f data which in turn means
that the findings are less likely to be distorted by interpretation; they will be
objective and unbiased. Post positivism led me away from positivism in a useful
direction but still did not give me a route to understanding how a group o f girls
described their relationship with physics. This journey took me towards
constructivism.
79
Creswell (2007) describes social constructivism thus:
Individuals develop subjective meaning o f their experience. These
meanings are varied and multiple. Often these subjective meanings are
negotiated socially and historically. In other words, they are not simply
imprinted on individuals but are formed through interaction with others.
p20
Understanding a phenomenon is formed through the participants and then-
subjective views. When these participants provide their meanings, they speak
from meanings that are shaped by both social interactions with others and from
their own personal histories (Creswell and Plano Clark, 2011). Therefore, when
collecting data it is important to collect and respect each participant’s view o f the
situations and use those views to develop a pattern o f meaning. In order to collect
this type o f research data the questions to be asked need to be broad and general
so that participants have the space and time to construct their meaning o f a
situation. The findings will, however, be the creation of the interaction between
the inquirer and the participants; the inquirer (me) will be interpreting the views
expressed by the participants in order to find broad patterns and come to broad
understandings o f the phenomenon. In this interpretation, I must recognise that
my own background and my own prior assumptions will shape my interpretation
o f the participant’s views. The findings will not be objective but subjective.
Combining post positivism with constructivism informed my methodological
approach. The research presented here has a positivistic aspect, a quantitative
questionnaire11, which was used to inform qualitative, constructivist,
investigations using group interviews and individual narratives to try to answer
the question o f how identities and self efficacy influence future subject choice. A
pragmatic perspective suggests that both o f these approaches can be explored
together, using mixed methods, since each is giving answers to a different part o f
the overall question (Flick, 2011). Pragmatism focuses on the consequences o f
the research and highlights that it is the research that is o f primary importance
11 Quantitative questionnaires are mostly associated with positivism, and in this research this was the case, but not exclusively so.
80
rather than the methods used to investigate it. Multiple paradigms can be used in
mixed method research; the researcher just needs to be explicit in their use and
reflect each world view in their reports. My work in this thesis reflects such a
mixed methods, pragmatic approach.
The initial proposal for the research was a case study o f two cases. This would
use a combination o f methods (questionnaire, small group interviews, lesson
observations and supporting evidence) to investigate the cases. As I progressed
with the data gathering, it became clear that I would not be able to complete all
o f these originally intended aspects o f the case study for each case due to issues
with one o f the schools around lesson observations. I therefore decided to focus
on the group interviews as the main data gathering tool. As I started to analyse
the data from the group interviews, I became interested in some o f the individual
stories that were emerging. The final iteration o f my methodology I am terming a
funnelling approach to a mixed methods methodology. I started with a
questionnaire given to a large number o f pupils, including 202 girls. From this
questionnaire I selected 43 girls to participate in group interviews. I then selected
a further five (that became four) girls for whom I would tell their stories in more
detail and three o f these I interviewed individually to add more data to what they
had given me in the group interviews. These final life stories are described using
narrative analysis. The rest o f this chapter describes the methodological
understanding that informed this research design and gives more detail o f each o f
these iterations.
Pilot Research
Prior to starting the work on this doctoral research I completed a Masters
research project (Thorley, 2010). My teaching background is in Further
Education and using my contacts in this sector I interviewed five girls12 who
were just completing their first year o f A-level study including physics. These
12 These were all girls who agreed to participate in my study after being asked if they wished to do so by their lecturers.
81
five girls had combined a study o f physics with a variety o f other subjects. I
found that I could split these girls into two groups - those who had included
physics as part o f a science A-level programme and those who had included
physics as part o f a mixed programme. All the girls said they were studying
physics because they were interested in the subject, but those who were
following a science programme had also included it because it would help them
to reach their future career goals.
I carried out a single, semi-structured, one to one interview with each girl for this
research, which I audio recorded and then transcribed. These girls were all 16 or
17 and used to studying in an environment where they were on a more equal
footing with the adults that they encountered than they probably would have been
in a school. Therefore, I felt that they were comfortable in talking to me in the
one to one situation and that they gave me detailed answers to the questions that I
asked.
I found that those girls who were studying physics in a mixed programme were
confident in themselves. They were prepared to study a subject because they
enjoyed it, not because they saw it as leading in any particular direction or to any
particular career. They were not influenced by what other people thought o f them
and not worried that they were studying a subject that other people might see as
being masculine.
In extending my research for the PhD study I was interested to see if this pattern
of physics study, either as part o f a science A-level programme or as part o f a
mixed programme, was evident in younger girls who were thinking o f choosing
physics for further study.
Case Study Methodology
As stated above, when I initially started on this research process I intended to use
a two case, case study approach. A case study approach seemed to be the best
82
methodological fit for my initial research aims. Yin (2009) defines a case study
as an investigation o f the how and the why o f a contemporary set o f events
within its real life context using multiple sources of evidence. The case is the
situation, individual, group or organisation that we are interested in (Robson,
2002).
There are many different types o f case study. Robson (2002) gives six examples
o f the usual types o f case study that are undertaken in social science research.
1. Individual case study - a detailed account o f one person
2. Set o f individual case studies - a small number o f individual case studies
where some common features are studied
3. Community study - study o f one or more local communities
4. Social group study - describes and analyses relationships and activities o f
groups
5. Studies o f organisations and institutions - for example the study o f a
school’s best practice in areas o f the curriculum
6. Studies of events, role and relationships - focusing on a specific event.
(pl 81)
My initial intention was to carry out two studies o f the identified schools (type 5
from the list above) looking at how they encouraged more girls to study A-level
physics. Once the researcher has decided on the type o f case study, they need to
be explicit about the purpose o f the case study. There are many reasons for
carrying out a case study and these could be classified as:-
1. Intrinsic - studying the subject o f the case out o f pure interest
2. Instrumental - to provide insight into a particular issue where the actual
case is o f secondary importance
3. Evaluative - to check how something (for example an intervention) is
working
4. Explanatory - an in-depth investigation o f a specific issue
5. Exploratory - finding out more about a perplexing issue.
Thomas, 2011, p53
83
I therefore class my case study as a combination o f an exploratory study (I was
interested in finding out more about the complex issue of girls’ progression onto
A-level physics) and an explanatory one (I was interested in carrying out an in-
depth investigation into the issue).
My original intention was to select schools for the two case studies as a critical
case sample (that is, ones where deductions can be made that if something
worked at that school then it would work in all schools) (Flyvberg, 2007). Case
studies, although they contain a subject and an analytical frame, are not good for
generalising. They are good at giving a rich picture o f the case within the
boundaries o f that case. Selecting schools as critical cases, however, would allow
a certain amount of generalisation to take place. When I actually visited the
schools, I realised that they were atypical (see below) so making generalisations
would be impossible.
Case studies are not a method in themselves, but are made up o f a variety o f
methods that all investigate a given event. These methods can include interviews,
questionnaires, lesson observations, background written data and discussions
with teachers and school officials. For my case studies I chose to use a
questionnaire, small group interviews, lesson observations and supporting
written data. All research could be called case study research; the distinction is
the amount o f information that is gathered using a variety o f methods and
different sources o f data and how that data is used to look at relationships and
processes (Gomm, Hammersley and Foster, 2000).
It was after I had completed the first round o f group interviews and had further
discussions with my contacts at both the schools that it became apparent that
carrying out lesson observations would be an issue for one o f the schools. I had
included lesson observations as part o f my case study methodology as case
studies include a variety o f data gathering tools used in conjunction to give an
overall picture o f what is happening in that case. Each method is used to
triangulate data from another method, so giving validity and reliability to each
individual data gathering method. I also realised that the data from my group
interviews was giving me very rich descriptions and that focusing on the group
84
interview data would be more valuable than trying to continue down the original
case study route and risk alienating one o f the schools by insisting on carrying
out lesson observations. The second iteration o f my project then became a case
study that focused primarily on the group interview data with supporting data
from the questionnaire.
The third iteration o f the project became one where the focus moved again to
individual narratives. As discussed above, this iteration could still be called case
study research as it is focusing on a set o f individuals. I am not calling them case
studies because I agree with Gomm, Hammersley and Foster that a case study
needs to include information collected by a variety o f methods and from many
sources. The three sources used here do not, in my opinion, give a broad enough
picture o f the individuals to allow the narratives to still be classified as case
studies.
School Selection
Previous research in the area o f girls’ progression onto post 16 physics has
shown that a high percentage o f A-level physics entries are from a minority o f
schools and that these schools are predominately single sex and selective (see
Murphy and Whitelegg, 2006a). Single sex, selective schools make up only a
small proportion o f the total o f secondary (post 11) schools in England. The
majority o f secondary schools in England are non selective, mixed sex schools
that are funded by the government.
I decided to use two mixed sex, non selective, government funded schools for my
cases. These types o f school are where the majority o f young people gain their
secondary education. I chose 11-18 schools as these would have sixth form
provision (i.e. they would offer A-level physics). The majority o f pupils in the
sixth form of an 11-18 school will have progressed into that sixth form internally
(i.e. they will have attended the same school pre 16 and have taken their GCSE
examinations at that school). I selected schools where a high number o f their
85
GCSE pupils progressed onto A-levels since these were schools where, I
conjectured, there was already a whole school ethos encouraging the study o f
subjects to A-level (Hampden-Thompson, Lubben and Bennett, 2011). However,
I not only wanted to choose schools that had a good overall progression onto A-
level physics but ones where there was a history o f above average (19%)
representation o f girls in their A-level physics classes.
The National Strategies13 data manager agreed to give me access to some o f their
data on schools that they had identified as having a higher than average
progression rate onto A-level physics in 2009.1 was not allowed access to the
data on all schools throughout the country so chose nine different geographic
areas. These areas were based on my home and that o f friends and family and
included all the schools within a 20 mile radius o f the homes that were included
in the National Strategies data. These two filters resulted in a list o f 152 possible
schools.
Further analysis o f the data for these 152 schools showed that 94 o f these schools
had less than 10 pupils entered for A-level physics. I did not have the data for the
overall size o f these school sixth forms, but due to the small numbers in the A-
level physics cohort I felt that these schools and their A-level physics cohorts
could be too small to offer me a large enough cohort o f pupils in years 9 and 10
for me to select girls to participate in the group interviews. I therefore rejected
these 94 schools.
I then looked more closely at the remaining 58 schools. The National Strategies
data filter for good progression only focused on overall A-level physics
progression, not just for girls. Since I was interested in schools with a higher than
average (19%) A-level physics representation for girls, I then eliminated those
schools which did not meet this criterion. I was left with 16 schools. I contacted
all 16 schools by letter and one school, Browning School14, replied that they
would be willing to work with me on this research.
13 The National Strategies were a government funded body who looked at specific subjects to increase achievement in them.14 Browning School is a pseudonym.
86
The second school, Hinton School15, that I worked with is outside the 20 mile
filter applied to the National Strategies data so did not appear on that data.
However, this school is within a one hour drive from my home so is accessible.
One o f the physics teachers from this school, a lead practitioner16 for science at
the time, attended a course at the Science Learning Centre Yorkshire and the1 7Humber looking at girls’ participation in physics. I approached this teacher at
one o f the course sessions since her school met my selection criteria and she
expressed an interest in my research. This meant that I now had two schools that
were willing to take part in the research.
It was when I visited both the schools that I found that they were atypical.
Although they were both mixed sex, non selective, government funded schools
they both had a higher than average school population o f White students and a
lower than average number o f students who were eligible for free school meals
(an indication o f socioeconomic background) (for full data see Chapter 5). This
means that the schools are comparable to each other but not with all other
schools in England.
Questionnaire
The initial research tool was a questionnaire (see appendices 1 and 2). It was
designed to be used to find out some basic information about all those year 9 and
10 girls who had the predicted attainment to allow them to progress to study
physics at A-level.
The initial intention of the questionnaire was to select girls to participate in the
group interviews (see below) by asking just a few questions about future subject
choices and the reasons for those choices. On reflection additional questions
were added to it so that data could also be gathered about impressions o f teaching
15 Hinton School is a pseudonym.16 This teacher had responsibility to work with her colleagues to improve the quality o f learning and teaching in science.17 This centre is based within the university of study.
87
and teachers, how pupils felt about physics and about physics self efficacy. The
answers to these questions were used to support the selection o f interview
participants (see Chapter 6).
The questionnaire was issued to all Year 9 and Year 10 pupils (both girls and
boys), at both schools, who were predicted to be able to gain at least a grade C
for GCSE Science or GCSE Physics. It is these pupils who are assumed to have
the academic attainment needed to study AS and A-level physics. This was done
because the teacher contacts at both schools asked that the questionnaire be given
to all members o f a class as this would be easier for the teachers to administer.
This now meant that I had questionnaire data for both girls and boys and so I was
able to carry out a small scale comparative descriptive statistical analysis (see
Chapter 5).
The final questionnaire had five groupings o f questions - questions about future
subject choices, about attitudes to science/physics lessons (see below), on
opinions on science/physics teachers, about how they felt about physics and their
physics self efficacy and finally some standard questions about socio-economic
background and ethnicity as well as asking if the respondent would be interested
in participating in the interviews. There were a mixture o f open and closed
questions and questions where the answer was a 3 point Likert scale. A Likert
scale is a recognised format where respondents indicate their level o f agreement
or disagreement with a statement by choosing from a set o f categories (Aldridge
and Levine, 2001). Often, a five point scale is used by having both strongly agree
and agree as well as strongly disagree and disagree. However, in many reports o f
questionnaires, the strongly agree and agree (and strongly disagree and disagree)
categories are reported together (personal observations). In my design, I only
offered three choices o f answers since the overall purpose o f the questionnaire
was to select group interviewees and to offer a broad picture o f views on
science/physics teaching and teachers and physics in general. In section two the
question from the UPMAP questionnaire was changed from a five point Likert
scale to a 3 point Likert scale for the answers. Another reason for changing the
UPMAP questions from a five point to a three point Likert scale was so that they
had the same number o f choices as the questions from Bennett and Hogarth’s
(2009) study used in section three; i.e. all questions in the questionnaire had the
same number o f responses.
Asking about the lull range o f future subject choices, not just whether the
respondents were going to choose physics or not, was included so that I could
choose the groups for the interviews (see below). I was also interested to find out
what range o f subjects pupils were thinking o f choosing to see if the traditional
mix (either all sciences or all humanities) was still being chosen or whether more
pupils were thinking o f taking a wider mix o f subjects post 16.
The second section asked about science and/or physics at school. The year 9
questionnaire asked about science whereas the year 10 questionnaire asked about
physics. This differentiation between the years was introduced because both
schools told me that they did not separate out the three sciences in year 9 and that
many pupils might not be able to distinguish between the subjects. In year 10,
both schools taught the sciences in separate classes so asking specifically about
physics was not an issue. This section o f questions was directly based on
questions from the UPMAP (2008) Physics Year 8 questionnaire. Blalock et al.
(2008) in their review o f instruments used for measuring attitudes towards
science found that many researchers preferred to reinvent the wheel rather than
use existing instruments and that this resulted in many instruments not
demonstrating good validity or reliability since they had not been rigorously pre
tested (Babbie, 1990). Since the UPMAP researchers had reported that they had
tested their questionnaire, I believed that using one o f their questions would add
to the validity and reliability o f my instrument. It also meant that in my analysis
o f the data I could directly compare my results to those gathered in the UPMAP
research. I asked questions about science and physics lessons so that I could
relate my findings to the literature about attitudes to science. This literature
found that, in general, pupils did not enjoy school science as much as other
subjects.
Section three asked about science and/or physics teachers. This question was
taken directly from the study o f Bennett and Hogarth (2009) discussed in
Chapter 2, with no alterations. Again, using a question from a previously tested
89
instrument increased the validity and reliability o f my instrument. This question
focused on the students’ attitudes to teachers and teaching and the interest the
teachers fostered in science or physics. It has been reported in the literature that
teachers play a major part in influencing future subject choice. Bennett and
Hogarth report that the agreement with this statement decreases as students get
older. I wanted to see if pupils at the schools in this research followed this
pattern.
The fourth section asked respondents to choose words that described how they
felt about physics and to write a sentence describing a ‘physics type o f person’.
Two self efficacy questions, based on questions from a standard self efficacy
questionnaire (Schwarzer and Jerusalem, 1979) were also asked. This group o f
questions was asked to see if physics self efficacy could be linked to future
physics choice and to see if the girls held stereotypical views o f what a physics
type o f person is.
The final section o f the questionnaire asked for data on gender, ethnicity and
socioeconomic standing o f both parents/guardians if known. At the end o f the
questionnaire, respondents were asked to tick as to whether they would be
interested and willing to take part in the group interviews.
Data from the questionnaire was analysed using SPSS. A code book (see
appendix 3) was developed to allow input o f the data from all the questionnaires
(both girls and boys). The open ended questions were thematically coded.
Descriptive statistical analysis was performed on the data (see Chapter 5). Using
descriptive statistics allowed me to investigate relationships between boys and
girls at both schools and for both year groups and to investigate similarities and
differences between those boys and girls who were thinking o f and not thinking
o f choosing to study physics (discussed further in Chapter 5).
90
Lesson Observations
Observation is a method that allows researchers to observe and record people’s
behaviour, action and interactions within a given setting (Hennink, Hutter and
Bailey, 2011). During an observation the observer will watch what people do,
listen to what they say and how they say it and observe how people interact with
one another. In an observation the researcher may observe from the position o f
‘complete participation’ or from ‘complete invisibility’ or from somewhere
between the two depending on the observations they want to make and their
involvement with the people being observed.
As part o f the original case study proposal, I wanted to observe girls in their
physics or other science subject lessons. My interest was in how the girls
interacted with each other (for example, if they worked in small groups, did they
work in groups they chose themselves or in groups allocated by the teachers; did
they work in single sex or mixed groups and what roles did they take on in those
groups); how they participated in the class (for example, were they willing to ask
and answer question); and how the teacher interacted with girls (for example, did
the teacher focus on boys or girls and did the teacher ask the same sort o f
questions to both boys and girls). For these observations I would not focus on
girls who were part o f my interview groups but all girls in the classroom.
Observations would not be completely invisible as the girls (and boys) would be
aware that I was in the classroom, but they would not be aware o f what I was
observing or who I was observing and I would not interact with them unless
asked to do so. The teachers would be aware that I was interested in girls and
physics but not the specifics o f what I was observing in their classroom. I had
made the teachers aware that I was not observing to assess their teaching and that
the focus was on the girls not them (see appendix 12).
I was able to carry out observations in only one o f my two schools. On both
occasions that I observed lessons (see timeline in appendix 14) I was given a list
of lessons that I was welcome to observe and was free to choose the ones I
wanted to see. The list was chosen by the head o f science and included both
91
physics and science lessons for years 9 and above and for a number o f different
teachers. In all o f the lessons I observed, the teacher welcomed me into the class.
During the lessons I made notes o f my observations (based on the list above) and
at the end o f the lesson wrote down my overall impression o f the lesson
including how the girls interacted with each other, with the boys in the class,
with the teacher and about their participation in the activities undertaken.
Interviews
Following on from the questionnaire I carried out small, semi-structured group
interviews. I originally planned to use three rounds o f group interviews as my
main data gathering tool for the case studies. The first o f these group interviews
was used to talk to the chosen girls about their subject choices and what
influenced them to make those choices (see appendix 6 for interview schedules
and Chapter 6 for more details about the interview process). The second round o f
interviews focused on teaching and teachers in both physics lessons and the girls’
favourite lessons and the third round o f interviews on identity and self efficacy
and the nature o f physics.
Active interviewing
A semi-structured interview can be used to obtain descriptions o f the life world
of an interviewee with respect to interpreting the meaning o f the described
phenomena (Kvale, 1996). Interviewing is not now seen as an interviewer
‘mining’ an interviewee’s knowledge without any interaction. Holstein and
Gubrium (1995) present the case for the active interview. They say:
Both parties are necessarily and unavoidably active. Each is involved in
meaning-making work. Meaning is not merely elicited by apt questioning
nor simply transported through respondent replies - it is actively and
communicatively assembled in the interview encounter. Respondents are
92
not so much repositories o f knowledge as they are constructors o f
knowledge in collaboration with interviewers.
Holstein and Gubrium, 1995, p i7
Opponents o f this idea o f interaction between the interviewer and interviewee
cite that this active approach to interviewing can introduce bias into the
responses and data gathered. Holstein and Gubrium counteract this by saying:
The active approach to interviewing might seem to invite unacceptable
forms o f bias. This criticism only holds, however, if one assumes a vastly
restricted view o f interpretive practice. Bias is a meaningful concept only
i f the interviewee is seen to possess preformed, pure information. But if
the interview responses are seen as products o f interpretive practice, they
are neither preformed nor pure.
Holstein and Gubrium, 1995, p i8
Rapley (2007) puts it more succinctly:
Interviewers should not worry about whether questions are too leading -
they should just get on with it.
Rapley, 2007, p i6
It was important, therefore, that I was aware o f my part in these group
interviews. Not only was I the person asking the questions, but I was interacting
with the responses that the interviewees gave and trying to develop these
responses by asking further questions. My position as an interviewer needed to
be thought about at all times.
Semi-structured interviews can be carried out as one-one or in small groups. I
chose to use small group interviews rather that one-one interviews for a number
of reasons. Group interviews are polyphonic in nature; they allow for a broader
spectrum o f respondents opinions than one-one interviews (Frey and Fontana,
1991).The groups formed here were not o f unknown people but were o f groups
where, if not friends, then each group member would at least know the others.
93
This allowed the interviews to be more discussion based than just question and
answer (Bohnsack, 2004). Working in groups rather than one-one means that
there is not as much pressure on the relationship between the interviewer and the
interviewee. A group can provide prompts to develop the talk when participants
agree, disagree and respond to others (Macnaghten and Myers, 2007). The group
allows the interviewer to identity a range o f issues but also to understand how
those issues are discussed in the group (Hennick, Hutter and Bailey, 2011).
Group interviews have been said to offer some respondent triangulation
(Denscombe, 1995) where events and attitudes are subjected to peer scrutiny.
However, this aspect can also lead to some o f the participants dominating the
discussion and others being ‘lost’. The interviewer has to work to ensure that this
does not happen. I also chose to use group interviews rather than one-one
interviews because o f the age o f the girls. I felt that girls o f this age would be
more willing to share their thoughts and feelings about a subject in a small group
with their peers rather than in a one to one situation with an, at first, unknown
adult.
Interview sampling and conduct
Girls were selected and then asked to take part in the small group interviews
based on their questionnaire responses.
1 8At Browning School, 37 year 9 girls and 56 year 10 girls completed the
questionnaire. Of these, 20 girls in year 9 and 29 girls in year 10 agreed that they
would be willing to take part in the small group interviews if asked to. Girls were
then selected from those who had agreed to be interviewed (for full details o f
interview group selection see Chapter 6).
At Hinton School,19 52 year 9 girls and 57 year 10 girls completed the
questionnaire. Of these 27 girls in year 9 and 33 girls in year 10 agreed that they
would be willing to take part in the small group interviews if asked to. Again
18 For more details about the school see Chapter 5.19 For more details about the school see Chapter 5.
94
girls were selected from those who were willing to be interviewed and details o f
these girls are given in Chapter 6.
During the first round o f small group interviews, issues around the chosen
groupings arose at Browning School. The first o f these was to do with numbers
in the group due to absences, but since this still left groups o f three or four I went
ahead with those girls who were present. The second issue was about the make
up o f two groups. When I contacted the school with my interview selections, I
did not explain why I had chosen which girls to go in which groups, apart from
the fact that they were either year 9 or year 10 groups. On the day, two girls
swapped groups because o f their other school commitments. This meant that my
year 9 Yes group now had a No (no science) girl in it and that the No (no science)7 f )group had one o f the Yes girls in it. Since I was not made aware o f this until the
first o f the changed groups turned up for their interview, I did not feel that I
could say no to the interview and reschedule as I was very dependent on the good
will o f both the girls and the school for agreeing to take part in my research. I
therefore made a decision that I would go ahead with these changed groups and
see what came out o f the discussion.
At Hinton School, for the first round o f interviews, the only issue that arose was
a couple o f pupil absences, but this did not change the nature o f the groups, just
reduced the numbers in a couple o f them.
Interview data processing
For the group interviews, I had decided to record them using audio only and then
transcribe them fully and start to analyse them before the second round o f
interviews. For the one-one interviews I had carried out for my MRes research I
had only used audio recording and had found that this was an unobtrusive way o f
recording the interviews. Therefore for the group interviews I decided to do the
same. I decided not to video the group interviews as I felt that this would be
20 For details o f what Yes and No groups are, see Chapter 6.
95
intrusive and that the girls, and myself, would not feel comfortable knowing that
all that they did in the interview would be recorded visually. I also felt that the
knowledge that a video camera was recording could lead to ‘performing for the
camera’ whereas using a small digital voice recorder would be forgotten and that
the girls would be more relaxed during the interview.
The process o f transcription is both interpretive and constructive (Lapadat and
Lindsay, 1999). Transcription can also be thought o f as the first process towards
analysing the data (Kvale and Brinkmann, 2009). This is due to the many
decisions that need to be made about the nature and form of the transcript
produced.
For this research project I decided that I would produce a transcript o f the
recorded interviews that reproduced each spoken word (or at least 90-95% of
them) but did not record long gaps o f silence or lots o f “urns”. This gave a
predominately denatuaralist transcript (Oliver et al. 2005). I did include any
idiosyncratic elements o f the speech, however, if I felt that they contributed to
the main discussion. These were mainly OKs and Yeahs when the girls were
agreeing with what others said, and also the numerous Tikes’ that appear to form
a major part o f young people’s speech patterns in today’s language.
I am not an audio typist and as Agar said (1996) ‘transcription is a chore’ (p
153). The main thing that I found difficult was distinguishing between the voices
o f the interviewees. Identifying a change in voice was easy; it was recognising
which o f the interviewees it was which was the difficult part. My research
questions focus on how self efficacy and identity, in particular, can affect choice.
I wanted to be able, over the series o f interviews, to track both an individual
girl’s thoughts and feelings on these aspects as well as any emerging group
themes. Therefore, I needed to find a way o f transcribing that met these research
objectives (Oliver et al. 2005).
Full transcription o f the first interviews from the audio recording only did not
happen due to this issue around transcription that I had not anticipated, mainly
the need to ascribe each quote to individuals. I could not do this from audio
96
alone. This meant a rethink around how I was going to carry out the subsequent
interviews and how I was going to overcome my transcription issues.
In order to be able to fully ascribe each quote to each participant when going
from the audio to the written, I needed to revise my research method. I decided
that for the second and third round o f interviews, I would video the interviews as
well as audio record them. On reflection, I decided that my reluctance to video
the interviews was based on my poor previous experiences o f being videoed.
Modem video recording equipment is much smaller and more discrete than in the
past. I needed to remember that for young people today, electronic means o f
communication are readily available and readily used in all areas o f their lives.
They might not be as reluctant to be videoed as I thought. I discuss ethical issues
around videoing below.
As discussed above, one issue that remained from the first round o f group
interviews was being able to identify individual speakers and match up what they
said to the transcription. I overcame this by asking the girls to listen back, as a
group, to their recording and used a hard copy o f the transcript to identify what
they said. This was an interesting process in its own right. The girls were, in
some cases, surprised at what they had said during the first interview. This
ranged from astonishment that they had been able to compose such clear ideas
about their future choices to telling me that they had completely changed their
ideas about their choices since the interview. I noted all o f these comments
down. Comments were also made about how they spoke. Many o f them were
surprised at how often they said ‘like’ and at how often they spoke in fragments
rather than whole sentences.
Member validation or member checks has been defined as ‘the researcher’s
interpretations presented to the subjects o f an enquiry for discussion o f their
validity’ (Kvale and Brinkmann, 2009, p325). In this case, I presented the girls
with the transcripts o f their first interview where only a small amount o f
interpretation had taken place. Validity has been described in many terms in
qualitative research - quality, rigor and trustworthiness to name a few
(Golafshani, 2003). In my case, I was using the participants to identify who said
97
what in the first interview. Their comments allowed me to make notes about their
perceptions about what they had said and about the reproducibility o f their
comments. The girls did not deny that they had said what I had transcribed - they
listened back to the tapes themselves. What did come out o f this process was
how what they had said in the interview was ‘the truth’ at that time but may not
be ‘the truth’ at another time. The talk in the interview captured their feelings
and thoughts at the time o f the interview, a ‘snapshot’, but these may not have
been reproduced at a different time. This is something to be aware o f when
analysing the data and building up a picture o f the girls’ developing physics
identity - an identity that also changes with time.
Transcription o f the second and third interviews was carried out using a
systematic approach. I first o f all transcribed from my audio recording, noting
down changes in voice. I then watched the video of the interview, ascribed
individuals to each piece o f transcription and corrected any errors in transcription
or missed changes o f speaker. If there were still any parts o f the interview that I
was not sure that I had transcribed accurately, I then went back to the original
audio recording and listened to that again. I did not use the video recording to
report on visual observations o f non verbal interactions that took place during the
group interviews. For these interviews, I solely used the video recording as a
means o f identifying which individual girls said what.
Interview analysis
As I transcribed the group interviews I made notes o f recurring themes and
themes that I felt needed to be followed up in subsequent interviews. These
themes were both deductive themes developed from the research literature (and
used to produce the questions for the interviews) and inductive themes that
emerged as the interviews were being transcribed. I had originally planned to
complete a full analysis o f each round o f group interviews before the next so that
developing themes could be added to the interview schedules if I felt that further
detail was needed. Due to the issues around the transcription o f the first
98
interview, I did not complete a full analysis o f the interviews after each round,
but did note down interesting themes as I carried out the transcriptions.
I carried out a full analysis o f the three group interviews once they had all been
completed. I wrote down themes that were both deductive and inductive. The
deductive themes were drawn from the interview questions and the inductive
themes emerged as I read through the interview transcripts and my notes from
the transcription process. I looked for repetition o f topics and used them to
produce a code book (see appendix 13), adding to the codes as I moved from one
round o f interviews to the next. The codes produced were hierarchical. For
example the overall theme o f yes to choosing physics had several sub codes
related to the reason for that choice (e.g. interest, needed for future career, best
school subject). I used NVIVO to code all the group interviews. The processing
o f the data was by ‘cutting and sorting’; identifying like quotes and collecting
them together (Ryan and Bernard, 2003). Once I had coded all the group
interview data in this way, I then reduced the number o f themes for discussion by
grouping together similar themes. For example, themes relating to self efficacy
(feedback, physics ability compared to friends, physics ability compared to class
and scored ability for physics) were all combined into one self efficacy theme.
Finally I printed out hard copies o f all the quotes I had allocated to each theme. I
used these to identify quotes to use in the discussion o f results (see Chapter 6).
The quotes given here were not identified at that stage by individual speaker but
just by which interview they had come from to try and overcome any
unconscious bias on quote selection; although for the analysis and discussion of
findings in Chapter 6 I did allocate names to the quotes so that any trends in data
between interview groups could be identified.
Developing Narratives
It was whilst I was transcribing each o f the three rounds o f group interviews that
I first started to feel that there were some individual stories that needed to be
told. When reading through the transcripts to identity themes for coding this
99
feeling grew. It was at this point that I decided to see if my initial feelings were
correct and I moved into the third iteration o f my research by focusing on
individual narratives.
Narrative enquiry is increasing being used in studies o f educational experiences
(Connelly and Clandinin, 1990). Although it is becoming more popular, narrative
research is difficult (Squire et al., 2008). Narrative can be thought o f as both a
phenomenon and a method. People can be thought o f as leading storied lives and
the narrative researcher not only collects and tells those stories but writes a
narrative o f that experience (Clandinin, 2006). Narratives have strength in that
human existence relies on the synthesis and analysis o f narratives that are
embedded in a social context (Bold, 2012). Narratives help to define the self and
personal identities.
Narratives are coloured by the context within which they are set. Understanding
the context is necessary for making sense o f the narrative (Clandinin and
Connelly, 2000). For example, a child will be influenced by their school, their
home life and their peers. Each child is an individual and is influenced by these
different contexts and situations in different ways over time. The child is not a
universal case that can be fitted into any context and who will perform in a pre
expected way. As Clandinin (2006) says, based on the pragmatic philosophy o f
Dewey, there are two criteria o f experience. Firstly, people are individuals and
need to be understood as individuals but always in a social context. Secondly,
experiences grow out o f other experiences which lead to further experiences.
Narratives are therefore not generalisable but capture the contextual influences
on an individual in a way that other research methods may not.
Narratives can fall into one o f three theoretical categories (Squire et al., 2008).
They can be narratives o f past events that are more or less constant; they can be
experience centred where stories about general or imagined phenomena are
explored which vary over time and across circumstances; and they can be co
constructed narratives that develop during conversations and can be shaped by
the audience. For the narratives I collected I focused on aspects o f the girls’ life
100
histories as related to their physics choices. Life history is defined by Watson and
Watson-Franke (1985) as:
any retrospective account by the individual o f his/her life in whole or in
part, in written or oral form, that has been elicited or prompted by another
person.
Watson and Watson-Franke, 1985, p23
Life histories can be thought o f as narratives o f past events but they are also co
constructed during the interview conversation. Life history research focuses on
the individual and how they understand and recall events from their past. The
stories we tell about our lives are privileged as well as troubled since they are
told in retrospect and have been reflected upon (Bruner, 2004). We tell the truth
as we now perceive it, not as it may actually have happened. We are storied
selves; we tell stories about ourselves all the time. These stories are the
cornerstone o f our identities with a close relationship between the stories we tell
and hear and who we are (Andrews, 2007). Our personal narratives are, however,
not just personal; they draw on cultural norms and the discourses that we
encounter in our day to day lives (Sclater, 2007). They allow us to investigate not
only individuals’ lives but also broader social processes. Narrative can be used to
look at whole biographical histories or just at important turning points during
life. In these one to one interviews I focused on specific turning points - how the
girls came to make their physics choices and what aspects o f their life histories
contributed to these choices.
When telling a narrative there are several qualities to look for in order to make
the narrative a ‘good story’. These were identified by Sikes and Gale (2006) as:
a. Liminality - those spaces where a reader opens their thoughts to
something new
b. Transgression - allows us to move beyond the actual to make emotional
responses to the narrative
c. Evocation - when we are emotionally moved by the narrative
d. Complexity - the narrative interweaves new ideas
101
e. Creativity - the narrative creates new concepts
f. Audience engagement - the narrative captures the attention o f the
audience by communicating in a certain way.
(P3)
There is, however, no single way that narratives are analysed to create this ‘good
story’ (Atkinson and Delamont, 2006, quoted in Bold, 2012). Stories generated
from interview data are often in a form of a summary o f events that have
happened rather than a detailed story (Watson, 1976, quoted in Bold, 2012).
Czamiawska (2004) stresses that when writing up a narrative, you must be
careful not to silence any voices. Narrative research relies heavily on
interpretation. The main voice o f a narrative will be the subjects, but as the
researcher I will also have a voice. Therefore, it is important that I am aware that
my voice does not overshadow that o f the subjects. Analysis o f the text from the
interviews (both group and one-one) was a cyclic process where the interviews
were transcribed, interpreted and then re-produced as personal narratives. This
process continues as the narratives are read by others and feedback is given and
they are then reworked. It is important in this process that the voice o f the subject
is the main one that is heard.
Analysis o f narratives is a complex process. During my analysis I identified
themes from the interview data, by repeated reading through o f the transcripts,
which provided an overall story o f each girl’s relationship with physics.
Narratives are not a search for the truth, but acknowledge the personal
experiences o f each girl as recounted at that moment in time. They are valid and
reliable since they are purposeful for the context in which they were generated.
To carry out the narrative enquiry I chose to use one to one interviews. I had
originally chosen to use group interviews because I felt that the girls would be
more comfortable in a group with their peers rather than just being interviewed
one to one by someone who, at the start o f the process, was an unknown adult.
After completing three rounds o f group interviews, I felt that I had built up a
rapport with the girls and that they would no longer be uncomfortable in a one to
one situation. These interviews were also going to look at aspects o f the
individual’s life history and there may have been aspects o f these which they
102
would not be comfortable sharing in a group environment (or had not shared
already).
For the one to one interviews I used a more structured approach than in the group
interviews. The questions I asked were different for each girl and were based on
their questionnaire answers and their previous interview responses. The dialogue
generated in the group interviews can lead to the creation o f a collective narrative
rather than an individual one. Here I was giving the girls the opportunity to tell
their own version o f events, but bearing in mind that they could still be telling
the narrative to suit the context; that o f a one to one interview with a person who
was interested in their relationship with physics. I could not assume that the
narrative told in this context would be exactly the same if told in another context;
however by using more structured questions I hoped to limit this variability.
I decided that I would not interview all the girls individually but select those
whom I felt had stories that would resonate with how girls come to make their
choices about whether to study physics post-16 or not (see below for selection
process used). I wanted to see if I could identify girls whose identification with
physics had changed over the course o f the interviews (either to a more positive
identification or to a more negative identification) and/or whose identification
with physics had been greatly influenced by others (e.g. teachers, peers, parents
or society).
In order to select the girls for these one to one interviews I produced a simple
spreadsheet with fourteen sections (name, school, year, yes or no to choosing
physics (questionnaire and interview), yes or not to choosing other science
subjects (questionnaire and interview), reasons for choosing/not choosing
physics (questionnaire and interview), physics words from questionnaire, physics
self efficacy question answers from questionnaire, physics self efficacy ranking
from interview, quotes about physics identity and physics self efficacy from the
interviews and finally any other relevant quotes from the interviews). I used
NVIVO to collate the data (generate a node) for individual girls from the
interviews and printed off transcripts for each o f the girls made up from their
collective contributions to each o f the group interviews. I then entered data from
103
the questionnaire and the collated interview transcripts onto the spreadsheet for
each girl. From this spreadsheet I identified five girls whose identification with
physics had varied over the course o f the interviews and from the original
questionnaire and/or whose identification had been greatly influenced by others.
I also chose girls who had contributed more than others to the interviews.
Of these five girls I decided to interview four o f them one to one. I decided not to
interview the fifth girl further for ethical reasons (see below) and also felt that I
had a good coverage o f her narrative from what she had said in her group
interviews. All o f these girls came from the same school (see Chapter 7 for more
discussion on this issue). On the actual day o f the one to one interviews, only
three o f the girls attended. I decided not to follow up the fourth girl because o f
times constraints, so ended up with just four narratives to describe and analyse
(one taken purely from the group interview data and three from the group
interview data supported by their individual interview data).
Ethical Issues
When planning this piece o f research, ethical concerns were addressed at all
stages. The research proposal was reviewed by the University ethics committee
and approval was gained before starting the research. The ethics approval form
used followed BERA guidelines (BERA, 2011). The schools identified from the
National Pupil Database as possible research centres were all contacted by letter
(see appendix 10). One o f these schools, Browning School, responded positively
to this letter and I visited the school and talked through the project with the Head
of Science. I presented the school with a detailed brief which outlined all the
components o f the, then, case study research (see appendix 11). The second
school, Hinton School, expressed interest in participating at a meeting. I again
visited this school and talked through the project with the lead practitioner for
physics and an assistant head. This school was also presented with the detailed
briefing pack. Following this meeting, both schools gave their permission for me
to proceed with the project.
104
The initial questionnaire asked for names so that I could select participants for
interview. A statement (see appendices 1 and 2) accompanied the questionnaire
stating that only the researcher would see the raw results (which are stored on a
password protected file) and that any results used would be annonymised. At the
end o f the questionnaire, respondents were asked whether they were willing to
take part in interviews, and only those who responded in the positive were
included in the selection process for the interviews.
Each o f the girls selected for the interviews was sent a letter (see appendix 8)
outlining the details o f the project and assuring them that all material used would
be anonymous. I also outlined that if they wished to withdraw from the research
project at any time then that was acceptable and no questions would be asked.
Participation in the interviews could result in identification o f areas of
themselves that the participants were not happy to share. The project brief made
them aware that they did not need to disclose any information if they were not
happy so to do. The consent form (see appendix 9) asked them if they were
willing to take part in the group interviews and if they were willing for the
interviews to be audio recorded. Before the first interview I checked that they all
understood what I was asking them to participate in and again confirmed with
them that they were willing to take part. For the second and third round o f group
interviews I also video recorded the interviews. Further verbal consents were
obtained before videoing took place. The three girls who attended the individual
interviews were asked verbally to give further consent that I could interview
them individually.
Debriefing occurred at the end o f each interview when I chatted with each group
off the record. The girls were informed that if they wished to read the interview
transcripts before they were used in the research they could. Due to the problems
with transcriptions, the transcripts from the first group interviews were read
whilst the girls listened to the audio recording and annotated the scripts to
identify when each o f them spoke. Although they were interested in this process,
not one o f them asked again to read their subsequent transcripts.
105
The names used for the girls in the project were chosen by the girls themselves.
By doing this I allowed them to have ownership o f their data with me as we
would be the only two people who could match actual people to the reported
data. The transcripts o f the interview data have been saved on a password
protected file. The video recordings have been saved on a password protected
computer and the originals deleted from the camera. The audio recordings have
also been downloaded to password protected files.
Ethical issues also come to the fore when writing up narratives. As mentioned
above, I did not follow up one o f my chosen stories with an individual interview
(Indiana). The story told as part o f the group interview had obviously caused
distress to her. I felt that I had enough data to tell her story from the group
interviews and did not want to distress her further by going over the story again.
As noted above when writing these narratives, I need to be aware that I have
considerable power to create a version o f reality that is mine and does not reflect
that o f the researched (Sikes, 2010). An ethical approach demands that I had to
endeavour to re-present their lives respectfully.
106
Chapter 5 The Schools and The Questionnaire
Results
Introduction
In Chapter 1 ,1 discussed the participation data for physics which shows that
approximately 20% o f the A-level entries are for girls. The Institute o f Physics
(2012) carried out a more detailed investigation o f the 2011 data looking at the
progression data from GCSE to A-level. This showed that no girls went on to
study A-level physics from 46% of the schools.
In Chapter 4 ,1 described how I selected the two schools who participated in my
research. These schools were chosen due to their higher than average progression
of girls onto A-level physics. In this chapter I describe those schools in more
detail. In Chapter 4 1 also described the questionnaire. In this chapter I present
some o f the results from those questionnaires for both schools.
The Schools
Browning School
Browning School is a comprehensive school that is located two miles from the
centre o f a large town. The school became an academy in 2011. The school has
approximately 1300 pupils with just over 300 in the Sixth Form. It has a
designated specialist status and was also designated as a Teaching School21
during the research.
21 Teaching schools are schools deemed by Ofsted, the government body which oversees quality in education, to be outstanding and that work with others to provide high-quality training and development to new and experienced school staff. They are part of the government’s plan to give schools a central role in raising standards by developing a self-improving and sustainable school- led system.
107
At the time o f the research, the science department had a team o f twelve teachers
supported by four technicians and two teaching assistants. Science was taught in
ten laboratories, two o f which were designated as sixth form teaching rooms. Of
the twelve teachers, three taught physics.
For GCSE the school taught the AQA syllabus. For A-level the Edexcel Salters
Homers course is followed for physics. In 2012, 34 students sat the AS physics
examinations and 23 the A2 examinations.
The GCSE results for 2012 showed that o f the 194 pupils who sat the
examinations, 91.3% gained five plus A* - C grades including Maths and
English, well above the national average o f 58.2%. 94% of these pupils
continued into further education, with 72% remaining at Browning School. For
Science 90.3% o f pupils gained an A* - C for the core GCSE and 86.3% an A* -
C for the additional GCSE. Overall the pupils at this school demonstrated a
higher than average attainment at GCSE.
Of the 34 pupils22 who took the AS physics examination in 2012, all but one
passed with 13 gaining a top grade. For the A2 examination there was a 100%
pass rate with four pupils gaining an A* and a further 7 an A grade. I was not
able to access data that showed the percentage o f girls in these cohorts or
whether they had progressed internally, but comments from staff showed that the
majority o f their sixth formers had progressed internally.
Ofsted describe the school as a popular comprehensive school. As noted above, it
is graded outstanding . They state that most o f the pupils are o f White British
background but that the percentage o f pupils from ethnic minorities has increased
in recent years. The number o f students whose first language is not English is
low for a school o f this size as is the percentage o f pupils eligible for free school
meals and those with learning difficulties and/or disabilities.
22 Number of girls and boys not specified.23 The highest grade awarded by Ofsted in school inspections.
108
My survey was answered by 199 pupils. The tables below show the reported
ethnicity o f the pupils and the reported socioeconomic background o f their
parents/guardians.
Table 5-1 Reported ethnicity o f pupils in survey sample.
Ethnicity % of pupils in survey sample
White 89
Black 1
Asian 2
Mixed Race 5
Other 3
Table 5-2 Reported socioeconomic background o f parents/guardians o f pupils in
survey sample.
Socioeconomic Mother’s Father’sGrouping background (%) backgroun
Professional 49 47
Clerical 22 11
Senior Official 2 7
Store workers 5 5
Skilled Manual 2 17
Semi-skilledManual
9 1
Unskilled 3 0
Don’t Know 4 8
Unemployed 9 3
This data shows that the majority o f the pupils who completed my survey
described themselves as White and had parents who came from a professional
background. This does not reflect the UK ethnicity or socioeconomic background
109
statistics, so care needs to be taken when comparing data from this school with
other schools.
Lesson observations
In my initial request to the schools, I proposed to use lesson observations and
informal teacher interviews as part o f the data collection methods. Browning
School was very welcoming and said that when I was in school carrying out my
interviews I could observe as many lessons as I wanted to. Over two separate
occasions (see timeline, appendix 14) I observed four physics classes and three
chemistry classes24 ranging from year 8 to year 12.
My overall impressions o f the lessons were o f well planned lessons with a
variety o f activities taking place. The teachers were confident in their subject
knowledge and were prepared to answer questions from pupils as the lesson
progressed. Pupils were mainly on task and participated in the lesson as required.
In the four physics lessons I observed, I took particular note o f how the girls in
the class interacted with each other, with the boys in the class, with the teacher
and how much they participated by asking and answering questions. I also noted
how the teacher interacted with the girls and if there was any observable
difference between this interaction and that with boys. I observed two year 10
physics lessons, a year 11 lesson and a year 12 lesson. These were given by two
different teachers.
The two year 10 classes were on different aspects o f the electromagnetic
spectrum. In both these classes girls were prepared to put up their hands to
answer questions. The teachers chose a selection o f pupils to answer the
questions. In both classes there were a minority o f girls who did not appear to
engage with the lesson. One o f the teachers tackled two such girls at the end o f
her lesson and told them that she expected them to participate more fully in the
241 observed chemistry classes because these were the subjects being taught on the day I was in school and this gave me an opportunity to get an overall feel for the school.
110
next lesson otherwise notes would be made in their planners25. In the other year
10 class, when the group split up to carry out practical work, some o f the girls
worked in pairs whilst others worked with a boy. In one such girl/boy pairing the
girl took charge o f the experimental work but in another pairing the girl just
scribed. In one question and answer session one boy tended to dominate the
session and was asked to respond most o f the time; however in another session it
was one o f the girls who put her hand up and answered most o f the questions.
The year 11 physics lesson observed was a preparation lesson for an upcoming
GCSE practical assessment. The session started with a question and answer
session recapping previous experiments similar to the one being prepared for.
Questions were answered by a mixture o f pupils. The teacher responded well to a
question asked by a girl who did not understand something and he used a good
analogy to explain his point. When the practical work started, most o f the girls
worked in pairs with each other. In one mixed paring the girl carried out the
experiment whilst the boy scribed.
The year 12 physics lesson was about collisions and was mainly a practical
lesson. There were 15 pupils in this class, five o f them girls. Only one o f the girls
was thinking o f continuing onto A2 physics26. Three o f the girls worked together
in one group, whilst the other two girls worked in groups with boys. In the all
girl group, the girls worked well together and split up the responsibilities easily.
One o f the girls in one o f the mixed groups was very passive and allowed the
boys to set up the equipment and take all the readings. In the other mixed group,
the girl was responsible for recording the readings and doing the calculations
needed.
At Browning School I also spent time in the staffroom talking to teachers and
talked to the teachers I observed following their lessons. All the teachers felt that
there was an issue about the number o f girls who chose to study A-level physics;
they wanted more to take it. Although they had a reasonable number who took
25 Planners, or diaries, are used in school for students to record their homework tasks and for teachers and parents to record comments about work or behaviour.26 Information from informal discussion with the five girls during the practical.
I l l
AS, less o f them continued on to take the full A-level. For a number o f years the
school had participated in a scheme to introduce girls to engineering by taking
them on organised visits (some o f the girls did mention this scheme during the
interviews). The teachers felt that this was a positive move towards encouraging
more girls to take physics and engineering but described it as a slow process.
The high percentage o f pupils who attained high grades for GCSE sciences
indicates that prior attainment would not be a barrier to pupils (and by
assumption girls) progressing onto A-level physics. In the classes I observed, the
majority o f girls participated hilly in the classes and I did not observe any
noticeable bias by the teachers towards the boys (either in asking or answering
questions). Overall, I would argue that the prior attainment and teaching
observed would not be an obvious barrier to girls taking A-level physics.
Hinton School
Hinton School is a comprehensive school situated on the edge o f a large town
similar to the town where Browning School is situated. The school became an
academy in 2011. The school has approximately 1750 pupils with over 500 in the
Sixth Form. It has two designated specialities and it became a Teaching School
during my research.
At the time o f my research, the science department had a team of twenty teachers
and six technicians. Of the twenty teachers, six taught physics.
At GCSE the school offers pupils a choice o f three programmes; core and
additional GCSE Science; the three sciences as separate GCSEs and a GCSE in
Applied Science. At A-level, the physics syllabus delivered is AQA.
The GCSE results in 2012 showed that 99% o f pupils gained 5 A* - C grades
(national average = 79.5%) with 91% gaining A* - C grades including English
and maths (national average 58.9%). For science, 90% o f the GCSE cohort in
112
2012 achieved two or more GCSEs at grade C or above. This school, as with
Browning School, demonstrates a much higher than national average attainment
at GCSE.
The 2012 A-level results show that 57% o f the A-level grades were at A*, A or B
(national average = 53%). For physics 54 pupils sat the AS examination and 26
the A2 examination. I was able to obtain the breakdown o f numbers o f boys and
girls for this 2012 data (see tables 5.3 and 5.4).
Table 5-3 AS Physics gender breakdown
Student type
Girls (internal progression27)
Girls (external progression28)
Boys (internal progression)
Boys (external progression)
Table 5-4 A2 Physics gender breakdown
Student type Number
Girls (internal progression) 1
Girls (external progression) 2
Boys (internal progression) 20
Boys (external progression) 3
For the AS cohort, o f the 41 pupils who progressed internally, 22% were girls.
Overall, this AS cohort had 24% girls. The national average for girls taking A-
level physics is 20%. For this cohort, the total percentage o f girls was just above
the national average and the majority o f these girls had progressed internally.
These percentages show that for this cohort, female take up o f A-level physics
27 Studied for GCSE at this school28 Entered school in sixth form having taken GCSEs at another school.
Number
9
4
32
9
113
was good. The picture is not so good for the A2 cohort. Of the 26 pupils who
took the A2 examination, only three were girls and two o f these entered the sixth
form from outside the school. I do not have the AS figures for this cohort, but it
would be worrying for female A-level physics numbers if either this was a true
reflection o f the number o f girls who started the two year A-level programme or
there was a high drop out rate between the AS and A2 years.
Ofsted describe the school as a highly popular, mixed comprehensive school
which is significantly larger than average. It was graded outstanding. They state
that virtually all o f the pupils are o f White British background. The number of
students whose first language is not English is very low, as is the percentage o f
pupils eligible for free school meals and those with learning difficulties and/or
disabilities.
My survey was answered by 259 pupils. The tables below show the reported
ethnicity o f the pupils and the reported socioeconomic background o f their
parents/guardians.
Table 5-5 Reported ethnicity o f pupils in survey sample.
Ethnicity % o f pupils in survey sample
White 91
Black 2
Asian 1
Mixed Race 3
Other 2
114
Table 5-6 Reported socioeconomic background o f parents/guardians o f pupils in
survey sample.
Socioeconomic Mother’s Father’sGrouping background (%) backgroun
Professional 49 58
Clerical 21 10
Senior Official 2 7
Store workers 4 3
Skilled Manual 2 13
Semi-skilledManual
5 1
Unskilled 2 1
Don’t Know 2 4
Unemployed 12 2
As with Browning School, pupils at Hinton School are predominantly White and
from professional backgrounds. This means that the cohorts o f pupils who
completed the survey from both the schools are comparable but that they do not
reflect the national average.
As I outlined in the section on Browning School, I originally requested that I be
allowed to undertake lesson observations and informal teacher interviews as part
of my project. Although Hinton School did sign up to frilly participate in the
project, when I tried to firm up times when I could carry out lesson observations
they were not possible. Also, although I was welcome to make a cup o f tea and
eat my sandwiches in the science staffroom, I did not have the opportunity to talk
about my project in detail with the science staff, even though I requested this on
several occasions.
The GCSE data from Hinton School shows that there is not an issue with prior
attainment being a barrier to pupils progressing onto A-level physics. The 2012
AS Physics cohort data shows that in that cohort there was a just above average
115
number o f girls with many o f them progressing internally. Headline figures o f
this type can mask a more complex picture o f why girls do and do not choose to
continue to study physics post 16. Using a qualitative approach, as I have done,
can help to give more details about the reasons for these choices.
The Questionnaire Data
The questionnaire was answered by 458 pupils. The breakdown from each school
is shown in table 5.7 below. These pupils were all selected by teachers at each
school as having the current attainment needed to achieve a grade at GCSE that
would allow them to progress onto A-level physics if they so chose.
Table 5-7 Pupils who answered survey.
Girls Boys
Year Year Year Year
9 10 9 10
37 56 44 62Browning
School
Hinton School 52 57 65 85
I would have expected that both the year cohorts would include approximately
the same numbers (schools tend to recruit approximately the same number o f
pupils each year). Fewer year 9 pupils at each school completed the
questionnaire. This could be an indication o f fewer pupils at this age being
predicted as having the necessary future attainment to achieve a good GCSE
grade or that there was not time for all classes to complete the questionnaire. For
year 10 at Hinton School, 18 more boys completed the questionnaire than girls.
This could be an indication that there are fewer girls overall in this cohort or that
there are more boys in the higher attainment sets. The pupils at each school who
116
answered the questionnaire were chosen by the teachers. Although all the pupils
at each school had, in the opinion o f their teachers, the current attainment needed
to be able to progress onto A-level physics if they so chose, these measures of
attainment may be different between the two schools. I would not expect this, but
since I did not ask for the measures used, I cannot definitely say that this was not
a reason for the different numbers who answered the questionnaire.
The data from this questionnaire give a ‘snapshot’ view o f the opinions o f pupils
at the two schools at the time the questionnaire was answered. Comparison o f
pupils is problematic. Comparison o f results between the years at each school is
also problematic. Observations can be made about the two year groups at the
time o f data collection but not o f changes in opinions from one year to the next.
Possible A-level choices
The pupils were asked to list up to five possible subjects that they were thinking
o f choosing to study for A-level. A wide variety o f A-level subjects was selected
by the pupils as possibilities. It must be bom in mind when analysing these
results that these are just possible future choices, not actual ones and that asking
about choices in science lessons may have introduced a bias (see Chapter 4).
117
Chart 5-1
Browning Year 9 A-level choices
n
■
1 -j ■■-n■
kill 1 B.ll . ,ol, l 1 II II
Subject
■ Browning Year 9 Boys■ Browning Year 9 girls
In Year 9 at Browning School 20 boys (45% of boys in the survey) and 4 girls
(11% of girls in the survey) indicated that they were thinking of choosing to
study A-level physics. It was the most popular future choice for the boystbsurveyed (not including other subjects) and 9 most popular amongst the girls.
Chart 5-2
Browning Year 10 A-level choices
Jl I .
xo
Subject
□ Browning Year 10 boys□ Browning Year 10 girls
118
In Year 10 at Browning School 32 boys (52% of boys in the survey) and 15 girls
(27% of girls in the survey) indicated that they were thinking of choosing to
study A-level physics. It was the most popular future choice for the boys
surveyed (not including other subjects) and 5th most popular amongst the girls.
Chart 5-3
Hinton Year 9 A-level Choices
45
40
35
30 +
fc 25-J-nEz 20
15 4-
10
5 4
J 1 I___ I i . r I) I
Subject
■ Hinton Year 9 boys □ Hinton year 9 girls
In Year 9 at Hinton School 41 boys (63% of boys in the survey) and 10 girls
(19% of girls in the survey) indicated that they were thinking of choosing to
study A-level physics. It was the most popular future choice for the boys
surveyed (not including other subjects) and 7th most popular amongst the girls.
119
Chart 5-4
Hinton Year 10 A-level Choices
E 30 --
JELa A rfi m
s s s v 7 ////////
■ Hinton Year 10 boys □ Hinton year 10 girls
Subject
In Year 10 at Hinton School 42 boys (49% of boys in the survey) and 12 girls
(21% of girls in the survey) indicated that they were thinking of choosing to
study A-level physics. It was the 2nd most popular future choice for the boystVisurveyed (not including other subjects) and 8 most popular amongst the girls.
In 2011 the national picture for A-level uptake (Gill, 2012) showed that physics
was the third most popular subject for boys and the 21st most popular for girls
(excluding general studies). Overall 10.6% of the A-level cohort chose physics;
18.4% of the male cohort and 4.0% of the female cohort. The figures from my
survey are higher than this, possibly due to the criteria used to choose the pupils
who answered the questionnaire (i.e. only those who already had the attainment
needed to go on to study A-level physics and other A-levels), and these only
show possible choices not actual choices. The schools chosen were also ones
where there was already a history o f high progression onto A-level physics and it
has been shown that where there is already a higher progression onto a subject
this will be repeated in future years.
120
Why choose or not choose physics?
The questionnaire asked the respondents to describe why they were thinking of
choosing physics or why they were not thinking o f choosing physics. Similar
answers to this open ended question were coded as one response.
As discussed in Chapter 2, previous research has shown that subjects are chosen
for further study because o f enjoyment or because they are needed for future
career choices. Subjects are not chosen due to low interest (or boredom) or
because o f poor performance. The reasons given for thinking o f choosing or not
choosing physics are tabulated below.
121
Table 5-8 Reasons for Thinking o f Choosing A-level Physics
Reasons Girls Boys
Year 9
(n=14)
Year 10
(n=27)
Year 9
(n=61)
Year 10
(n=74)
Physics is needed for my
future career
57 44 36 29
I enjoy physics 29 33 52 58
Physics is mathematics based
and I am good at mathematics
0 15 5 1
I am good at physics 14 0 0 4
Choosing physics makes me
look good
0 0 5 3
Physics is boring 0 4 0 0
No reason given 0 4 2 5
(Note - figures given are percentage o f that cohort)
The two main reasons given for thinking o f choosing to study physics at A-level
are because physics is enjoyable and because physics is a subject that is needed
for a future career goal. Amongst girls who are thinking o f choosing physics the
most common reason is for a future career rather than an interest in the subject
whereas for boys interest is the most common reason. 15% o f year 10 girls are
thinking o f choosing physics because it is a mathematics based subject and they
consider themselves good at mathematics and 14% o f year 9 girls are thinking o f
choosing physics because they feel they are good at it. The percentages in both o f
these categories for boys are much lower. One reason given by a small
percentage o f boys only was that they considered that taking an A-level in
122
physics gave them kudos - it made them look good compared to other boys
because they had chosen a hard subject.
Table 5-9 Reasons for Not Thinking o f Choosing A-level Physics
Reasons Girls Boys
Year 9
(n=73)
Year 10
(n=85)
Year 9
(n=46)
Year 10
(n=73)
I am not interested in physics 27 36 28 42
I don’t need physics for my
future career
36 31 35 15
I am not good at physics 22 27 9 19
I haven’t decided yet what I
am taking for A-levels
5 1 22 12
No reason 9 5 7 12
(Note - figures given are percentage o f that cohort)
The reasons given for not thinking o f taking A-level physics were as predicted by
previous research. More girls than boys said that they were not thinking o f taking
physics because they were not good at it. This could be linked to a lower self
efficacy for physics amongst girls than boys (see later section). A reasonable
number o f boys had not yet thought about what subjects they were going to take
for A-level. I have included these pupils in the not choosing physics figures but,
of course, they could in the future actually choose physics. I have included them
here because at the time o f the questionnaire they were not thinking o f choosing
physics.
123
Physics words
One o f the questions on the questionnaire asked respondents to select from a
range o f words what they felt about physics. The words were:-
Enjoy Like Hate Bored
Frightened Excited Anxious
Worried Difficult Easy Interesting
Respondents were asked to select as many as they wanted and to add further
words if they wanted. For analysis I recorded how many times each word was
selected and allowed up to five words per respondent, which gave an average
number o f responses. This meant that each respondent could have a different
number o f responses to this question. I recorded multiple responses and looked
for overall trends rather than absolute numbers for each word.
Rather than looking at similarities and differences between the girls and boys in
each year group at each school, I looked at the similarities and differences
between girls and boys who were thinking o f choosing physics and between girls
and boys who were not thinking o f choosing physics. The words chosen by each
of these groups are represented below using a ‘word cloud’ format (see appendix
4 for data used to produce word clouds). This format shows the most commonly
chosen words as larger than those not chosen so often.
124
Chart 5-5 Girls who are thinking o f choosing A-level physics
frightened
difficulteasy| interesting® I o“g | like
3 " 5 x 2 . ^ .cD'CDosenjoya Q _ c c l
Chart 5-6 Bovs who are thinking of choosing A-level physics
. ..difficult a - p J l k C
# £ excited=§|iriterestingo ‘a § . CD a n x j o u s
e S . 3'—*.2 ! easyO CfQ
rD3
a
125
For both girls and boys who are thinking o f choosing A-level physics their most
commonly chosen word to describe how they feel about physics is interesting
followed closely by like. However, the girls group also describe physics as
difficult more frequently than did the boys group and also felt bored by physics
more than the boys. Recent research (Pike and Dunne, 2011) has shown a trend
towards choosing physics and some other A-level subjects because they are
thought of as being hard and that this gives extra kudos to those students who
choose them. The choice of bored is not an obvious one. It could be suggested
that bored is linked to easy (i.e. an easy subject does not stretch so you become
bored). Another explanation could be that the teaching is not inspiring but this
questionnaire will not provide answers for this.
Chart 5-7 Girls who are not thinking of choosing A-level physics
boredHadifficult$ £ et ^ worried! “« | hate
Ctq ^ e n j o y
CDa
126
Chart 5-8 Boys who are not thinking o f choosing A-level physics
difficulthate.
enjoy
I IS boredh-*
g S a o l i k e
^.frightened
r - r -h r -f
3 cdOQ ^For girls who are not thinking o f choosing A-level physics their two most
commonly chosen words to describe their feeling about physics are difficult and
bored. These are both also chosen by boys who are not thinking o f choosing
physics but bored was chosen more often that difficult. For both groups of non
choosers, many pupils also chose like and interesting.
How do I compare myself to others?
As discussed in Chapter 3, a high self efficacy (a person’s perceived capability
for learning at a designated level) has been suggested as a good predictor of
future subject choice (Britner and Pajares, 2006). Boys are also reported as
having a higher self efficacy than girls (Meece and Jones, 1996). One question
asking about issues related to physics self efficacy was posed in the
questionnaire. This asked the respondents to rank their physics ability relative to
the rest o f the class and to rank their liking o f physics relative to their friends.
127
Ranking their ability relative to their class reflects the mastery factor o f self
efficacy; they believe that they are capable o f achieving in physics relative to the
similar others in their class. Ranking their liking o f physics relative to friends
reflects that someone often believes that they will be more successful in a subject
that they like; they will put more effort in and work harder to achieve.
The results for the statement asking pupils to rate their ability in physics relative
to the rest o f their class (see below) show that pupils who are thinking o f
choosing to study A-level physics report a higher self efficacy than those who are
not. They also show that boys in general report a higher self efficacy than girls.
For girls, year 10 possible choosers o f physics report a slightly lower self
efficacy than year 9 possible physics choosers whereas the opposite is true for
boys. For all groups, except the boys in year 10, there is a small percentage o f
possible choosers who report that they are amongst the worst in their class for
physics.
Table 5-10 Comparing mv physics ability to the rest o f mv class
Girls Boys
Year 9 Year 10 Year 9 Year 10
(n=)
Y
14
N
73
Y
27
N
85
Y
61
N
46
Y
74
N
73
In my class, I am one o f the
best at physics
21 4 15 2 31 15 53 8
In my class, I am about the
same as most people at
physics
71 68 81 67 61 70 44 74
In my class, I am one o f the
worst at physics
7 21 4 19 2 4 0 7
No answer given 0 7 0 12 7 11 3 11
(Note: figures given are percentages for that cohort)
128
The results for the second statement, asking pupils to rank their liking o f physics
relative to their friends, show similar results (see below). When asked about
liking physics, boys who are possible choosers o f physics have a much higher
liking o f physics than girls who are possible choosers. Again, there is a small
group o f possible choosers who also say that they like physics a lot less than their
friends, and this percentage is higher for year 10 that year 9.
Table 5-11 Comparing how much I like physics to mv friends
Girls Boys
Year 9 Year 10 Year 9 Year 10
(B P )
Y
14
N
73
Y
27
N
85
Y
61
N
46
Y
74
N
73
I like physics more than my
friends
14 8 33 2 48 9 47 7
I like physics about the same
as my friends
79 51 41 52 26 60 32 45
I like physics a lot less than
my friends
7 30 15 39 7 23 10 29
No answer given 0 11 11 7 20 9 12 19
(Note: figures given are percentages for that cohort)
Both o f the measures reported above (how I compare my physics ability to the
rest o f my class and how much I like physics compared to my friends) could be
used to predict possible choosers o f physics. I was interested to see if the same
group o f students both reported a high belief in their physics ability and that they
liked physics more than their friends. For those who were thinking o f choosing
physics, only 5% of girls (n=41) reported that they both believed that they were
one o f the best in their class for physics and also liked physics more than their
friends whereas 29% o f boys (n=135) chose both these statements. Since both o f
these statements are related to self efficacy, these results show agreement with
129
previous research that for possible choosers o f physics boys have a higher self
efficacy than girls
Teachers and interest in science or physics
One o f the questions asked on the questionnaire was taken from Bennett and
Hogarth (2009) and asked respondents to respond to the statement ‘my
science/physics teachers make me more interested in science/physics’
Respondents were asked to agree, disagree or neither agree nor disagree with the
statement and then select a further qualifying explanation. (Pupils in year 9 were
asked about science teachers and those in year 10 about physics teachers since
differentiation o f the science subjects did not occur in either school until year
10).
Analysis o f this question showed that many respondents had not fully understood
how to complete the question as outlined above and had placed ticks in boxes
across the range o f answers. I recorded these as mixed answers. These responses
show a limitation o f this type o f question where respondents are asked to give
one response about all their science/physics teachers. Teachers vary and this mix
o f answers reflects this variation where pupils may consider that one o f their
science/physics teachers does/does not make them as interested in the subject as
another.
The instructions given with the questionnaires stated that pupils were not
required to answer questions they did not feel able to. A high number did not
answer this question. This could also be an indication that they either did not
understand how to complete the question o f felt that they could not make a
collective judgment about their teachers in this way. Overall, because o f the large
number o f mixed answers and missing answers, the data needs to be looked at for
trends rather than focusing on the numbers.
130
Bennett and Hogarth (2009) did not differentiate their data by gender or by
whether pupils were thinking o f choosing to go on to study science subjects at A-
level or not. Their sample was o f pupils from four schools with 78 year 9 pupils
(47% male and 53% female) and 98 year 10/11 pupils (49% male and 51%
female). These four schools were all mixed comprehensives and were not
selected based on their progressions data. If I use the data just from those pupils
who answered the first three statements I have a sample from Browning School
o f 47 year 9 pupils (57% male and 43% female) and 72 year 10 pupils (51% male
and 49% female) and from Hinton School o f 63 year 9 pupils (52% male and
48% female) and 82 year 10 pupils (60% male and 40% female). These samples
are comparable.
Table 5-12 Comparing mv results to Bennett and Hogarth
Year 9 Year 10
B
(n=47)
H
(n=63)
REF
(n=78)
B
(n=72)
H
(n=82)
REF
(n=98_
% o f students who agreed that teachers made them more interested in science/physics
74 29 31 54 41 31
% o f students who neither agreed nor disagreed that teachers made them more interested in science/physics
15 41 39 31 17 34
% o f students who disagreed that teachers made them more interested in science/physics
10 30 30 15 41 35
B = Browning School, H = Hinton School, REF = from Bennett and Hogarth
These results (table 5-12) show that the year 9 pupils at Browning School have a
much higher liking o f their teachers than those in Bennett and Hogarth’s study
whereas those in year 9 at Hinton School have a slightly lower liking. For both
131
my schools, the year 10 pupils have a higher liking for their teachers than those
in Bennett and Hogarth’s study. However, at Hinton School there is also a much
higher disliking o f teachers. Pupils in year 10 at Hinton School either like or
dislike their teachers with only 17% o f those included in this sample having a
neutral view.
The analysis o f my data for this question can be reported differentiated by
gender, year group and by whether the respondent was thinking o f choosing
physics for A-level or not.
132
Table
5-1
3 Do
mv
te
ache
rs m
ake
me
more
in
teres
ted
in sc
ience
or
phys
ics?
IhcaCD
ON
ca<d
CA
om
VhcaCD
O n
caCD
>«
oZ
CA(D
><
com ON in
( N
c a
CD
O
Z
CD
>*
OZ
CD><
VO
I
in00
CN
co
I
m
CNCN
Oco
On
ON
in
oCN
oo
oco
CN
in
vo
CN
OO
ONCN
CNco
voCN
mco
coCO
CNCO
VOCN
00CO
in
oo
CN
t"-
CN
ca
Ica<D
ca-aT3
CDCD
kbca
*G(DT33CAl+Ho
o >
T3CD
<D!—ioaa(D
43CD'Ocaa
CAo*CA
S3(D
GCDO
VhoGT3CD
S)caj-iCD
43'(DGO
43£G<D
T 333
O '
CD
0aaCD
43CD
T 3
1CAi-iCD
43ocaCD
ca43-♦-»
t 3CDCD
kbca
. w*3
CA
43
CDO33
. aOCA
CD-4-*CACDt-iCD
.1
CAl-H. 8
3CD
ca43-4->
T3CDCD
kbcaCA
. §£
33CDTOG
•+-» CA
<-1—iO
O '
T3CD
-4-JCACD
CD
aCD
43-*->CDT3caa
CAo
43
CDo33woCA
CA33ca0033
Os °O '
roco
Students who were thinking o f choosing to study physics for A-level were more
likely, except for year 9 girls, to agree that their teachers make them more
interested in science. It was also these groups o f students who were more likely
to answer this question ‘correctly’; they were less likely to give mixed answers
or to not answer the question at all.
Science and physics lessons
One o f the questions asked was similar to one asked on the UPMAP
(Understanding Participation Rates in post-16 Mathematics and Physics)
questionnaire (2008) asking pupils to respond to statements about their
science/physics lessons. The results are given below for each school year and
separated into those pupils who are thinking o f choosing physics post-16 and
those who are not. This allows comparison in each school year group o f what
boys and girls who are both thinking of choosing physics and those who are not
thinking o f choosing physics think about their science/physics lessons and to see
if there are any reportable similarities or differences.
134
Table
5-1
4 Br
owni
ng
Scho
ol y
ear
9CN
&£P h
C/5
OPQ o
CN
45P.
c a
CD
<Nco
o
45p .
C/5
h—Ia
o£
CAo
&45P .O-«->CACD
><
voCN
O
<
<
inCN
m
oVO
On
<N
O n
Oin
om
in
oo"d-
inco
oco
o<N
Om
vo
O nCN
inin
inCN
m
CAVhCD CDo -2 *S § g r ° $>> w 'wa s sCA •<-! O
! 8 S3” S H<d .2? E 1—1 o ^(U CA g
oo
m
VOCO
mCN
oCN
mm
co
CN"d"
mm
inCN
P £ *•2 2 o 0 +-> “ C P
'p «S 4h 45 Ph P
P X P .'S I—( O P CA
m
JSs-*->CD%X
*>■CN
■*frin
00
in
oco
min
On
in
vo
oin
oin
CAPCD
T3
PoCA• w*
T3O
-h—>
■Sptsop jpo
poCACAOCDP CD • OCA
Bo
'p 1<d
in
voco
O nm
m
oCN
invo
vo
mco
00m
inCN
inr -
44c a
£CDP
CO
oOn
CO
ON
00
inCN
inCN
oin
44S -iO£
*c3o
p
00
CD
CO
00"d'
OnC O
C OC O
oin
VO
CN■'d-
CNin
inCN
inC-*
CAPoCACACD
CDOPU
"o
CAS-ICD
45opCD+-•CDOP
•2oCA
CD44
<DCD
kbp
CDCD
kbp
i-iopCDCD
kbp»-iCD
45’ <DP
inco
CDCD
kbp
CD00pBCDOS-iCDPCD
kjPCD>•00CACDl-lp00
PCACD-H~>o
5 -
Tabl
e 5-
15
Brow
ning
Sc
hool
yea
r 10
oco
COo&£P
Oin
cn>HoCQ
o£ <
00$h H
O
CNCO
COO££O h
O1/1<o
COo
P h.
o-4->o£ <
in
££O h
<D
O S
"itP"
SO"d-
in
(N
IN
CO
o(N
COT t-
CO
(N<N
in
OSCN
SO
ncs
oso
S-H<d
hPoP<d
<D
co
P
I 'p
p3
p CDP Vho 3CO C+HPCD ' B
3 PiO
CD S-HO CDP
3 Ho PCO P£ PO
hP OH-> COp
_ p H P op 3 • ^
3p ’ p p
&CD p CO
com
CO
SO
oocs
soSO
OsCN
Os■p"
CNCN
CN
CO
oSO
CDrP W P
« 3 > 3P ^ hP >>|
P §0 g1 -a<U| ' O
co O o +-*
t l
P pJ
O■p"
oin
CO
COso
in
•p-
in
co
ocoJo,PP>>atoo
‘S 'CD
OCN
CO
CO
CO
CO
COso
CNCO
INCO
CNCO
CO
CO
J5*p
MCO
£CDP
ICD
oCO
COm
so
CO
ooo
00CN
inCN
00Tf
oCN
CO
r-so
*o£
_oV->§PH gW) op CO• 5 co O <D 73 1—1n . wS '3
‘p 1 &CD ,£H I—I P
CO
IN
CO
CO
COso
CO
o
00■p"
co
COl - lCD
hPoP<dCOoCO
£p
tCD
£
CDCD
kbPco
CDCD
kbPco
«-HOPCDCD
kbP«-H
&CDP
S OCO
<DCD
kbp
co<DbDP
3CDCD1-HCDPCD
cbpCD>
‘5bCOCDS-hPbO
CpCOCD
H—>o£ ,
Tabl
e 5-
16
Hint
on
Scho
ol y
ear
9CNCN Q
oo>«Om
C/5
O
cao
££P h.
O+-»
o£
CAO
£PH
o-+->CACD
><
Jj,CAO
&P
P h .
O-*-»o
£
o
&is*P H
0)i *
oCO
VO
Os
<
VO
O NCN
CN
to
oCN
o
v oCN
toCO
O NCO
to
to
CNCO
CA
CD <DPo03 PS SS' 8P O . - "P
£ O O oCA rn
o—1 o0 ) CA
8 £ <D O
O ^ CA _ g
^ IsP Oh P x
P CD
3CD>-H
c £
PtfH
o«-HCD
■ 8ppp
cd
O CA-t-> P
P . oCD H—>
cdP h P&
H—>
cd *CA
CNCN
v oCN
CNt o
oCN
O NCO
O nCN
CO
co
o■'d-
oCN
P 52 +-« cd
> 3 p r
£ a
o g1/3 CA CA . 2 2
3 "P<D o Op tH
•a *a8 p> . ts& ap &
oCO
to
CO
to
to
co
O nCN
VO
ooo
PoCACAo
c d
8• Sh oCA
l '
o'p 1
c d
to
CNCO
''3-VO
to
r -CN
O Nto
to
O nCN
v ov o
oCO
MCA
£<DP
O n
O n
COoo
CN
CN
to00
oCN
ooo
*o£
_o%->o03t-HP h g
SP oP CA*S 1/3 O d
> . <D
• § ap aU ' o
v oCN
o
to
O nt o
oCN
ONCN
COv o
oto
oto
S-I
J§8c d
H—>
c dop<d
§ *<D
rS
<Dc d
fcbCdCA
<dCD
kbCdCA
Vh
8CDCD
kbcdVh<D
PH->' 5p
r"~CO
c dc d
kbcd
<CACD00cd
3cdoJ-HCDP hCDS-HcdPCD>
‘ SbCACDt-HP00
t f i
cdCACD
-4-Ho&
Tabl
e 5-
17
Hint
on
Scho
ol y
ear
10CO"a-
o&£P I
00o03
oo
O
o£
CN
1/3O
£o-*->CO<0
t-"a-
coo’Ss£p .o
1-1
o£
CN
<
3-
CN
CN
<
CO O • ^
£P
<
VO
00
oin
CN
coco
00in
oo
co"3-
ooCN
CNCN
O nCO
O nCO
CO
O nCN
O-a-
<uX>ccao
>>1/11+2 6 S s
^ T3 l+Hw ’ H o
S-IID
CO c o
•8 * j? 4304 s£ rva xh-H (0
C3
O co~ aT3 O <D ‘JO 43 ta P S35 ^ca w
r-t3‘
com
CN
CNco
in
CO
CO
v oCN
CN"3"
COCO
<D43 co+-» ca9 J* > 3 & r
^ & •—i £CO W £ £2 o 3 « .a<u> * 13
co O o +-“£> £P i ^
rt"
oin
O n
CN
CNC O
VOin
com
C O
O n
r-
o’ c o
p>>
>>O'o'Q
00CN
C O
mco
O nC O
'3-in
CN
inC O
T3"a-
inCN
o • ^CO>>
43P
44co£<DacVica(D
CN
oC O
r-vo
m
moo
O n
OCN
Ot"-
mCN
oom
%o£
la"■+3SP g op oG CO
c oO D>> 3o G* >>o 42-H P
CO■'3-
C'"CO
a-CN
CN
VOm
coCO
a--a-
coCN
inCN
S-1
J§3o1->coo
•CO
£p
I 'o
£
<L>(Dkbca
«DokbcaCO
l-l
§OOkbcaVi(D
43CDG
00CO
<L><Dkbca
CO<DtJ)ca"£«DOViOp<L>VicaG<D>• ^to<Dgtd)
caCO<U-Vio5 -
The results for girls in year 9 at Browning School cannot be reliably compared
between those who are thinking o f choosing physics and those who are not since
there are only four girls in the thinking o f choosing group. For the year 9 boys at
Browning School, the thinking o f choosing physics group generally have a
higher opinion o f their science lessons than those who are not thinking of
choosing physics. Comparing the two groups o f those pupils who are not
thinking o f choosing physics girls are more likely to look forward to their science
lessons, girls think that their teachers explain how science can be applied more
often than boys, girls feel they can discus their ideas more often, girls enjoy
practical work more than boys and girls like their science teachers more than
boys. However, more boys say that they enjoy their science lessons. This liking
of science lessons by those girls not thinking of choosing physics could be
because they like the non physics parts o f science but this cannot be confirmed or
denied from these results.
For year 10 at Browning School, girls who are thinking o f choosing physics
generally have a more positive attitude towards their physics lessons than those
girls who are not thinking o f choosing physics. The same trend is observed
amongst boys. Girls who are thinking o f choosing physics also have a more
positive attitude towards their physics teachers than boys who are not thinking o f
choosing physics. This more positive attitude amongst girls intending to choose
physics over boys who were not was also observed in the UPMAP work
(Mujtaba and Reiss, 2012a and 2012b). The boys who are intending to choose
physics have a more positive attitude than girls who are intending to choose
physics, again a view observed in the UPMAP work. Amongst those pupils in
year 10 who were not intending to choose physics boys generally have a more
positive attitude towards physics than girls, except that girls thought their
teachers were more likely to explain how physics could be applied to different
situations. This was again observed in the UPMAP work. Interestingly, all
groups o f pupils, except those boys who were thinking o f choosing physics, had
a similar liking for their physics teachers.
At Hinton School, the year 9 girls who are thinking o f choosing physics was
again a small group (10 pupils) so comparison o f percentages needs to be
139
circumspect. Generally the year 9 girls who are thinking o f choosing physics are
more positive about their science lessons than those who are not; except that
none o f the choosing group agreed that they liked their science teachers. The
boys who were thinking o f choosing physics were generally more positive than
the girls choosing group. Amongst the two groupings o f boys, those who were
not thinking o f choosing physics were more positive than the choosing group that
their science teachers explained how science could be applied to different
situations, that they had opportunities to discuss ideas in the lesson and that they
learnt new skills in science lessons.
The responses from the year 10 pupils at Hinton School were more varied. Girls
who were thinking o f choosing physics reported a more positive attitude than
those not thinking o f choosing physics for looking forward to physics lessons,
enjoying physics lessons and liking their physics teachers. However, the girls
who were not thinking o f choosing physics reported a more positive attitude to
those thinking o f choosing physics for saying that their teachers explained how
physics could be applied to different situations and for enjoying practical work.
For the boys, as expected, those who were thinking o f choosing physics had a
more positive attitude to physics lessons than those who were not thinking o f
choosing physics. Boys who were thinking o f choosing physics were also more
positive than girls who were thinking o f choosing, as seen for Browning year 10
and in the UPMAP work. Girls who were thinking o f choosing physics were not
generally more positive than boys not thinking o f choosing physics as seen for
Browning year 10 and in the UPMAP work, but were more positive in a few
areas (having the opportunity to discuss ideas in physics lessons, enjoying
physics lessons, learning new skills in physics lessons and liking physics
teachers). Of interest was that all year 10 pupils liked their physics teachers more
than year 9 pupils liked their science teachers. Of course, these may not be the
same teachers.
140
Discussion
As noted earlier (Chapter 2) Jenkins and Nelson (2005) found that girls preferred
biological sciences over the physical sciences. In the graphs showing possible A-
level subject choices, biology was more popular amongst these girls than either
chemistry or physics at both schools and for both year groups. For these girls,
history, English, geography and Art were the most popular subject choices. This
agrees with the findings o f Ryan (2011) and Pike and Dunne (2011) where girls
are more likely to choose subjects classified as feminine: the humanities and the
arts.
The responses to the questionnaire indicated that these girls are more likely to
choose physics if it is needed for their future careers. Examples from the
literature also show this (Pike and Dunne, 2011; Cleaves,2005; Reid and
Skryabina, 2002; Stewart, 1998 and William et al, 2003). Boe et al (2011) also
showed that subjects are chosen for further study if they have utility value; they
allow access to university courses. Physics can be thought o f as a gatekeeper
subject so many o f these girls may be thinking o f choosing physics to help them
progress onto more general science based university courses (such as medicine)
rather than onto courses with a high physics content. For the boys in my survey,
the reasons for choosing physics are not as clear cut. More o f these boys are
likely to choose physics because they are interested in the subject rather than
because they need it for a future career. Not needing physics to help them
progress into a future career was the highest reason given by the girls for not
choosing to study physics. It would be interesting to find out if the girls in my
survey (and generally) develop a career focus for subject choice earlier than for
the boys.
Linking to the question about why they were thinking o f choosing or not
choosing to study physics, the questionnaire asked respondents to choose words
that described how they felt about physics. For those girls who were thinking o f
choosing physics, the most common word chosen was interesting, as it was for
the boys who were thinking o f choosing physics. The second most common word
141
chosen by the girls who were thinking o f choosing physics was difficult. That
physics is described as a hard subject links with the commonly held binary
dichotomy, as described by Francis (2000), which describes physics as hard,
masculine and objective. Even though these girls are thinking o f choosing
physics, they still hold this generally held conception about physics. For those
girls who were not thinking o f choosing physics, their most commonly chosen
word was difficult. This reinforces the view expressed above and found in the
work o f Lyons (2006), Bennett and Hogarth (2009) and Pike and Dunne (2011).
As noted earlier (Chapter 3), self efficacy has been found to be a predictor of
subject choice (Britner and Pajraes (2006) and some research has shown that
boys have a higher self efficacy than girls (Heller and Ziegle, 1996 and Meece
and Jones, 1996). The results from the questionnaire show that the boys
generally report a higher self efficacy in physics than the girls for each o f the
questions asked. Since the boys also report a higher percentage o f choice to study
physics than the girls, it could be deduced that the higher reported self efficacy
leads to the higher choice. When combining the two self efficacy measures, the
boys demonstrate a much higher self efficacy than the girls. Amongst those
respondents who were thinking o f choosing physics, the boys reported a much
higher self efficacy for the combined questions than did the girls (29% vs 5%).
One question asked the respondents to comment about their science or physics
teachers and how much they felt that their teachers made them more interested in
science or physics. For Browning School the majority o f students felt that their
teachers did help them to be more interested in science or physics whereas at
Hinton School the responses were more neutral and a higher number felt that
their teachers did not help them to become more interested in science or physics.
When looking at the similarities and differences between the possible choosers
and non choosers groups, generally the possible choosers were more positive
about their teachers than the non choosers with the exception o f year 9 girls. The
influences o f teachers on which subjects their pupils will choose to study further
has been reported extensively in the literature (see Chapter 2). If teachers help to
make their pupils more interested in the subject then they are more likely to
choose to study it later. The data from my questionnaire gives some support to
142
this claim. When relating these results to those from Bennett and Hogarth (2009),
Browning School showed a higher number o f pupils saying that they felt their
teachers helped them to be interested in science or physics whereas Hinton
School pupils were below the percentages reported by Bennett and Hogarth. The
results from my questionnaire may be distorted by the high percentage o f mixed
answers to this question, but the general trend can be reported. These
questionnaire results are supported by the data from the interviews where the
girls from Hinton School expressed more variation in teachers and teaching than
the girls from Browning School.
In general, the results from the question asking pupils to discuss their science or
physics lessons show that they had fairly neutral views about the lessons except
for some areas. Browning year 9 pupils in general enjoyed doing practical work
in science lessons and felt that they learnt new skills; Browning year 10 pupils
again enjoyed doing practical work and also felt that their teachers applied
physics to different situations; Hinton year 9 pupils also felt that they learnt new
skills in science lessons as well as enjoying practical work but Hinton year 10
pupils only really enjoyed the practical work. Making lessons enjoyable by using
practical work was identified by the pupils that Osborne and Collins (2001)
interviewed as one o f the reasons that they enjoyed science lessons. Pupils
overall attitude to physics is another aspect that influences future subject choice
(see Chapter 2).
Using the responses from this data highlights some points that teachers and
schools need to be aware o f if they are trying to encourage more girls (and to
some extent more boys) to study A-level physics. Girls are interested in how
physics can lead to interesting and fulfilling careers. Information needs to be
made available about the variety o f careers that studying physics can lead to;
either directly or indirectly. Linked to knowledge o f future careers, is the
generally held understanding that physics is hard, boring and masculine. If the
subject itself is perceived as this, then careers linked to it will be too. Efforts
need to be made to contradict these commonly held beliefs.
143
Girls who are thinking o f choosing to study physics at A-level generally have a
more positive response to their teachers than those who are not. Students at
Browning School were more positive about their teachers than those at Hinton
School. Positiviness about teachers is a difficult thing to measure, especially
when using a tool that asked about science/physics teachers in general, not about
specific teachers. The differences between the two schools could just be a factor
o f the cohorts surveyed and these results may not be reproducible with other
cohorts. However, in general, it is important that teachers are aware o f the effect
they have on influencing students’ enjoyment o f subjects and their future plans.
This will be investigated further in the next Chapter.
The questionnaire attempted to measure the level o f physics self efficacy held by
the students. In general, boys reported a higher physics self efficacy than girls. A
high self efficacy has been linked to subject progression. The link between self
efficacy and subject choice is not fully explored in the questionnaire and will be
revisited in the next Chapter.
Overall the data gathered from the questionnaire can give a background overview
o f the attitudes o f these pupils to science and or/physics and some o f the
underlying reasons as to why they are thinking o f choosing or not choosing
physics. Numbers can be allocated to these reasons and to some o f the attitudes
expressed about science and/or physics lessons and teachers and physics
generally. The data cannot, however, give in-depth information as to why these
attitudes are held or why these reasons influence future subject choices. The data
cannot also explain subtle differences; for example why one respondent may be
thinking o f choosing physics but still report that they find it boring whereas
another who describes physics as boring is not thinking o f choosing to study it
further. These subtleties can, however, be explored by asking the respondents to
explain their reasons and their attitudes in an interview setting as described in the
next Chapter.
144
Chapter 6 ‘Do Only Polish Women Choose
Physics?’29
Introduction
In this Chapter I introduce all forty three girls whom I invited to participate in the
group interviews. For each girl I give a brief description based on her
questionnaire responses and explain why I chose her to participate in the group
interviews. Before describing the findings from the group interviews in detail, I
briefly outline the overall themes o f the three rounds o f group interviews and
describe how the interview process developed during each interview and for each
round. I then go on to describe the findings from the interviews in detail,
grouping the findings based on themes outlined in the interview schedules, on
themes based on the research literature reviewed in Chapters 2 and 3 and on
themes that emerged during the interviews. I conclude the Chapter with a
discussion o f the findings.
As described in Chapter 2, Holmegaard et al. (2012) noted research into choices
has focused on student background (British emphasis); using choice models to
predict choices (US emphasis); and linking choices to identity development
(Scandinavian emphasis). A common concern o f all is examining what
influences these choices. These can include future career aspirations, the
influences o f family, peers and teachers, and the image o f the subject which links
into how society views someone who studies that subject. Also in the mix is
ethnicity and socio-economic background o f the student.
Whilst making choices, we are carrying out identity work. All o f the above
contribute to how we see ourselves in relation to a subject. As discussed in
Chapter 3, our subject self efficacy is intertwined with our identity with respect
29 At the informal chat after the first group interview, Margery joked that as far as she was concerned only Polish women studied physics since these were the only ones she had heard about; she said that her physics teacher always talked about Marie Curie when he wanted to give an example of a women doing physics.
145
to the subject and how our subject self efficacy develops impacts on this identity.
The identity work takes place within the many figured worlds (Holland et al.,
1998) that we encounter during our day to day lives. For the girls discussed
below, much o f their identity work takes place within the figured world o f the
school and the figured worlds o f the individual subject classrooms.
Introducing the Interviewees
The answers given by girls on the questionnaire were the starting point for
selection o f participants for the group interviews (as discussed in Chapter 4). All
the pupils who completed the questionnaire were also asked if they were willing
to take part in the group interviews, and only those who ticked the ‘yes’ box were
included in the selection process for the group interviews.
The initial selection was into two groups - those who expressed an intention o f
choosing to study physics post 16 and those who did not. I then intended to split
those girls who were thinking o f choosing physics into two groups depending on
what other subjects they were thinking o f doing alongside physics as I did in my
Masters research (Thorley, 2010). Further selection was done by reading through
the responses given to the rest o f the questions on the questionnaire. Selection o f
these girls was not random - for example, I selected those who I felt gave
conflicting answers to different questions on the questionnaire; those who felt
they were good at physics but who did not want to continue to study it; and those
who liked other sciences but now hated physics. Brief descriptions o f the forty
three girls selected for the group interviews are given below based on their
questionnaire responses including details o f why they were selected. The
pseudonyms used were chosen by the girls themselves.
146
Year 9
Browning School
Group categorisation Girls in group
Yes - intending to choose A-level physics Kathy, Monica, Beryl
No - not intending to choose A-level physics but
intending to choose other science A-levels
Louise, Chloe, Heather,
Tasmina
No - not intending to choose A-level physics or any
other science A-levels
Ivy, Joey, Whitney, Zara
Total 11
In year 9 at Browning School, 20 girls said they would be willing to participate
in the group interviews. Of these 20 only three were thinking o f choosing physics
(in a mixture o f A-level programmes) so the Yes group was self selecting and I
was not able to split it into different A-level programme types.
Kathy
Kathy was thinking o f choosing physics alongside chemistry,
mathematics, English and photography. She wanted to go into
medicine and felt that most universities wanted physics at A-level.
Monica
Monica was thinking o f choosing physics as well as mathematics,
further mathematics, history and English for A-level. She was
thinking o f choosing physics because it was her favourite o f the
three sciences and also because her brother did it and that he made
it seem interesting.
Beryl
Beryl was thinking o f choosing physics, mathematics,
photography, textiles and art for her A-levels. She was not really
sure what she wanted to have as a career but felt that physics
would be useful to know for any future scientific career.
147
For those girls who were not thinking o f choosing physics at A-level (17), they
were split between those who were thinking o f taking other sciences but not
physics and those who were not thinking o f taking science at all. I therefore
decided to have two No groups to see if there were any similarities or differences
in their relationship to physics between girls who were thinking o f choosing
other sciences and not physics and those who were not thinking o f choosing any
sciences. I chose four girls for each No group. These choices were made by
reading through the answers to all the questions on the questionnaire and noting
down any interesting quotes (i.e. those that were distinctive or gave an insight
into what the girl thought about the subjcet) given for the open ended questions
and/or noting down conflicting answers. Selection o f the girls for these groups
was not a random sample.
Louise
Louise wanted to be a vet or a history teacher so was thinking o f
choosing a range o f science and humanities subjects for A-level.
She did not want to choose physics because it was one o f the
harder subjects for her and she also felt she was one o f the worst
in her class for physics. I was interested to find out why she did
not like physics but did like other sciences - what was it about
physics that she felt made it harder than the other sciences and her
one o f the worst in her class.
Chloe
Chloe also felt that she was one o f the worst at physics in her
class. She however found biology interesting and was going to
choose this for A-level. She thought her science teachers were
enthusiastic. Teachers have been identified as influencing future
subject choice and I was interested in seeing if Chloe’s
relationship with her different science teachers influenced how
she felt about physics.
Heather
Heather had not chosen physics even though she liked it more
than her friends because she felt there were more options in the
148
future if she did the other sciences. I was interested to find out
why she thought this.
Tasmina
Tasmina said that she didn’t need A-level physics, only biology
and chemistry, even though she did not explain why. She again
liked physics more than her friends even though when asked to
describe how she felt about physics she said that she hated it, it
was boring and it was difficult. I felt that if she found physics to
be so but still liked it more than her friends, then trying to get girls
interested in physics would be a very hard job.
Ivy
Ivy was not going to choose physics because she did not want a
job to do with physics. She felt that physics did not excite her and
that her teachers did not make it interesting or explain how
science could be applied to the real world. I was interested to find
out how her relationship to physics was influenced by her teachers
Joey
Joey was going to choose art and textiles for her A-levels. She
agreed that science lessons were interesting and that the teachers
made the subject interesting. She thought that being a physicist
would be interesting and well paid, but was just not for her. I
wanted to know why she thought this.
Whitney
Whitney liked her physics teachers and thought that she learned
new skills in science lessons and she particularly enjoyed practical
work. She liked physics but found it boring and difficult and felt
that it was not one of her strongest subjects. I was interested to
find out about these apparent contradictions.
Zara
Zara liked her science teachers and felt that she learnt new skills
in science lessons. She liked physics and found it interesting.
However she was not sure how much she liked physics compared
to her friends. Given that she liked physics and found it
149
interesting, why was Zara not thinking o f choosing to study
physics further?
Year 10
Group categorisation Girls in group
Yes - intending to choose A-level physics Florence, Delila, Alison,
Liwy, Patricia
No - not intending to choose A-level physics Kate, Margery, Lola, Eve
Total 9
Twenty nine year 10 girls who completed the questionnaire were willing to be
interviewed. Of these, only five were thinking o f choosing physics so I selected
them all and made one Yes group irrespective o f overall A-level programme.
Florence
Florence’s possible choices for A-level were physics,
mathematics, further mathematics and ICT. She was thinking o f
choosing physics because it was mathematics based and because
she wanted to study a science at A-level.
Delila
Delia was thinking o f choosing physics, biology, chemistry,
drama and history for her A-levels. She wanted a career in
medicine so thought that taking all three sciences at A-level
would help her achieve this aim.
Alison
Alison was thinking o f choosing physics, biology, mathematics,
chemistry and geography for her A-levels. She enjoyed physics
and thought it would also help her to achieve her career goal; that
o f being a vet.
150
Liw y
A combination o f physics, biology, chemistry, psychology and
mathematics was what L iw y was thinking o f choosing for her A-
levels. She was thinking o f choosing physics because she wanted
to take all three sciences to help her in her future career goal,
although she did not mention a specific goal.
Patricia
Patricia was thinking o f choosing physics because she really
enjoyed it, she loved learning about it and found it a very
satisfying subject. The other A-level subjects she was thinking of
choosing were art, business and design technology.
Of the remaining 24 girls who had all said they were not thinking o f choosing
physics, only a small number o f them had written anything in the open ended
questions so this reduced the number o f girls I could select No groups from. In
the end, I decided to have just one No group with a mixture o f girls who were
both thinking o f choosing other sciences but not physics and those who were not
thinking o f choosing any science at all. The four girls chosen for this No group
are described below.
Kate
Kate was going to choose mathematics and biology for her A-
levels but not physics because she was not that interested in the
subject. She found physics difficult but interesting. I was
interested to find out how she saw the relationship between
mathematics and physics and why she was choosing one subject
but not the other when they are thought o f as being closely linked
subjects.
Margery
Margery was going to chose PE, biology and chemistry for her A-
levels. She did not enjoy physics lessons and did not like the
teacher. She found physics to be boring, was worried about the
subject and couldn’t be bothered with it. I was interested to find
151
out why she liked the other sciences but, as she said, ‘loathed
physics with a passion’.
Lola
Lola was going to choose all humanities A-levels because she
loved those subjects. She also said that she liked physics less than
her friends and thought that it was boring and difficult but
sometimes interesting. I was interested to find out why she loved
humanities but did not like physics at all.
Eve
Eve was going to choose biology and photography for her A-
levels as well as Spanish and French. She thought that physics
was a necessary subject and could be interesting sometimes. I was
interested in finding out why she described physics as necessary.
Hinton SchoolYear 9
Group categorisation Girls in group
Yes - intending to choose A-level physics Annie, Summer, Josie,
Phoebe. Elizabeth
No - not intending to choose A-level physics but
intending to choose other science A-levels
Poppy, Scout, Samantha,
Jane
No - not intending to choose A-level physics or any
other science A-levels
Nora, Ruth, Doris, Ethyl
Total 13
There were 27 girls in year 9 at Hinton School who were willing to be
interviewed. Again, only a small number, five, were thinking o f choosing
physics. These girls formed one Yes group.
152
Annie
Annie was thinking o f choosing physics because it was her
favourite science subject and also because she did not like biology
and chemistry. Her other possible A-level choice was PE
Summer
Summer’s possible A-level choices were physics, geography,
mathematics and economics. She was thinking o f choosing
physics because it was her favourite science.
Josie
Josie was thinking o f choosing physics because she found it
interesting and she thought it would be useful. Also, her sister was
taking chemistry for A-level which she now regretted and wished
that she had taken physics instead. Josie’s other possible choices
were French and Italian.
Phoebe
Phoebe was thinking o f choosing physics with French, history and
English for her A-levels. She was thinking o f physics but the final
decision would be based on her GCSE results.
Elizabeth
Elizabeth was thinking o f choosing physics, chemistry, biology
and mathematics for her A-levels. She thought she was going to
be a vet so would need all the sciences to help her achieve this
goal.
Of the remaining 22 girls, they again fell into two clear groupings as for year 9 at
Browning School and the majority o f these girls had given answers to the open
ended questions so I again selected two No groups. This also meant that for year
9 at both schools I had similar grouping for the interviews.
Poppy
Poppy was going to choose biology and chemistry because she
needed those for a future career and had not chosen physics
because it would not be useful for a future career. She said that
she hated physics, found that it was boring and was bad at it. I
153
was interested to see how she compared her ability in physics to
her other science subjects.
Scout
Scout was going to choose biology and mathematics but was not
choosing physics because she felt that it was too hard. She felt
that she liked physics more than her friends, but found it difficult,
confusing and that she was anxious about it but she also sometime
found it interesting. I was interested to see if she could explain
these feelings further.
Samantha
Samantha said that she liked and enjoyed physics and that she
found it interesting. She also felt that she liked physics more than
her friends. This profile looked like someone who would choose
physics so I was interested to find out why she was not.
Jane
Jane had chosen biology and chemistry for her future A-levels.
However, although she mainly enjoyed and liked science she felt
that it depended on the class and the teacher. She felt that physics
was boring, even the practical work and she hated the subject.
This made me want to know what she particularly disliked about
physics - the subject or a teacher?
Nora
Nora wants to be a psychotherapist so did not feel that she needed
physics. She thought physics was boring and difficult and did not
see the point of what they were doing in science lessons. I was
interested to find out why she was so negative about science and
physics in particular.
Ruth
Ruth wants to become an actor or maybe a lawyer. She felt that
she was one o f the worst in her physics class and that she liked
physics a lot less than her friends. She did not think that she was a
physics sort o f person because she did not like giving only one
correct answer. This reason has been given in the past as to why
154
girls do not like physics so I was interested to follow up this
comment.
Doris
Doris said that she was not going to choose sciences for A-level
because she did not like them but that she would choose
mathematics because it was good for jobs. She also felt that
physicists were stereotyped in the media. She was the only girl to
talk about this aspect so I wanted to include her in my sample.
Ethyl
Ethyl did not really know what she wanted to do for her A-levels
and had only chosen politics. However, in her discussion about
science teachers she had highlighted that her enjoyment o f a
subject depended on whether the teacher liked the subject or not.
Since previous literature had highlighted teachers as an important
influencer o f subject choice, I thought she could have something
interesting to say on this aspect.
Year 10
Group categorisation Number o f girls in group
Yes - intending to choose A-level physics as part o f a
science programme
Moa, Emily, Sunnva
Yes - intending to choose A-level physics as part o f a
mixed programme
Rose, Charlotte, Lily
No - not intending to choose A-level physics Skye, Anya, Indiana, Ruby
Total 10
Of the 57 girls in year 10 who completed the questionnaire 33 were willing to be
interviewed. Six o f these girls were thinking o f choosing physics; three as part o f
a science programme and three as part o f a mixed programme. Rather than have
one large Yes group, I decide to have two as originally proposed based on my
MRes work.
155
Moa
Moa’s possible A-level choices were physics, mathematics,
geography, chemistry and biology. She wanted to study some
form of science at university so felt that physics at A-level would
be helpful.
Emily
Emily enjoyed physics and thought it would be helpful to her in
the future as she wanted to go to university to study science. Her
other possible choices were mathematics, geography and
chemistry.
Sunnva
Sunnva’s father was a physicist and she wanted to follow in his
footsteps. She also found physics to be interesting. As well as
physics she was thinking o f choosing mathematics, biology,
chemistry and history for her A-levels.
Rose
Rose’s possible choices for A-level were physics, history, French
and chemistry. She was not sure exactly what she wanted to do
except that it was something science based and felt that physics
would help her in this future career.
Charlotte
Charlotte was thinking o f choosing physics because she was good
at it and she understood it even though it was not necessarily her
favourite subject. Her other possible choices were geography,
French, mathematics and Spanish.
Lily
Lily thought she would choose physics because it kept a lot o f
doors open. Her other possible choices were English, philosophy,
politics and history.
Since I had two Yes groups for this year group, I decided to have just the one No
group as originally planned. The No girls were selected as for previous No
groups.
156
Skye
Skye’s answer to the question ‘are you a physics sort o f person’
was intriguing. In the answer she explained that she found physics
the easiest o f the sciences because she felt that she was a logical
thinker. She went on to explain that many people did not see how
this fitted her as she was also a Christian. An example o f two o f
her worlds not fitting, so something I wanted to investigate
further.
Anya
Anya wants to be a musician. She said that she hated physics and
found it hard. She felt that this was because she struggled with
mathematics and did not like the mathematics aspect o f physics.
She was one o f the few that talked about this link.
Indiana
Indiana was going to choose mathematics, chemistry and product
design for her A-levels. These are all physical sciences so I was
interested as to why she had not chosen physics as well.
Ruby
Ruby’s chosen A-level subjects were a mix o f subjects. She felt
that physics was boring and difficult and that physicists were
more interested in physics than a social life. She also felt that she
would not be able to hold a 5 minute conversation about physics
without ‘dropping o ff . Since she had very definite views about
physics, I though that it would be interesting to hear more o f
them.
Summarising the interview groups
From both schools and across both year groups, I had selected nineteen girls who
were thinking o f choosing to study A-level physics and twenty four who were
not. In the Yes groups, eleven o f the girls said that they were thinking o f
choosing physics because it would be a useful subject for their future career
157
goals. Seven o f the girls mentioned that they were thinking o f choosing physics
because they enjoyed it, they found it interesting or that it was their favourite
science subject. One went further than this to say that she was thinking o f
choosing physics because she was good at it. Two o f the girls said that they were
thinking o f choosing physics because they wanted to be like a family member;
one a brother and one her father. Just one girl mentioned the link between
physics and mathematics as the reason for thinking o f choosing to study it
further.
I split the No to choosing physics girls into two groups; those who were not
thinking o f choosing physics but were thinking o f choosing other science
subjects and those who were not thinking o f choosing any science subjects.
Those girls in the No to physics but Yes to other science subjects groups said that
they were not thinking o f choosing physics because it was too hard (six); because
it was boring (six); and because they did not feel they would have as many future
career options if they chose it (two). Two o f this group o f girls said that they
were one o f the worst in their class for physics, but four reported that they liked
physics more than their friends and one even reported that she enjoyed physics.
Three girls in this group related not choosing physics to the teachers; one felt that
her biology teacher was more enthusiastic than her other science teachers so she
preferred biology; one did not like her physics teacher and one said that her
future subject choices were dependent on her teachers.
Girls in the No Physics, No Science groups were not thinking o f choosing
physics because it was not needed for their future careers (two); because they felt
physics was boring (three); and that physics was too hard (four). However, one
girl reported that she found physics interesting and one recognised that being a
physicist could be interesting and well paid but that it was just not for her. Two
members o f these groups also said that their teacher did not make physics
interesting, but two other girls said that they liked their physics teachers.
Details o f the questionnaire responses for the interviewees can be found in
appendix 5.
158
Interview Themes and Process
The three rounds o f group interviews each had a pre-chosen focus. The first
interviews focused on their future subject choices, why they were going to
choose or not choose to study physics and what they felt influenced those
choices. The second interview focused on teachers and teaching, asking about
physics teachers and lessons in particular and then comparing them to their
favourite lessons and teachers (if this was not physics). The final group
interviews focused on the question ‘what kind o f person are you?’, the girls’
relationship with physics and their views on gender and choice in general. I used
a semi-structured approach to the group interviews (discussed in more detail in
Chapter 4) with a pre-prepared interview schedule (see appendix 6) but during
the interviews I allowed the girls the freedom to talk about any topic that came
up in the conversation even if it did not directly link to the main theme for that
interview. Not all groups talked about the same things and not all members o f the
group contributed to each line o f discussion. Not all o f the questions and prompts
on the interview schedule were used in each interview as I wanted the interviews
to be free flowing discussions rather than structured interviews. This meant that
on fully analysing the interview transcripts I found that there were some themes
that were discussed in all three stages o f the interviews and others that were only
discussed in parts o f one. Other themes only occurred with some groups whilst
others were found in all the groups. Also, some girls talked a lot more than
others. This meant some girls are quoted more than others and some girls not
quoted at all (see discussion on limitations o f data in Chapter 8). The interviews
were coded using both deductive and inductive codes (see appendix 13) (see
Chapter 4 for details o f analysis).
Exploring Reasons for A-level Physics Choices
As part o f the questionnaire I had asked the girls to give a reason as to why they
were thinking or not thinking o f choosing physics at A-level. To start the group
interviews, I asked each group to briefly say again why they were thinking o f
159
choosing or not choosing physics. For those who were thinking o f choosing
physics the first reasons given in the interviews were very similar to those
recorded on the questionnaire i.e. they were thinking o f choosing physics
because they were interested in it or they needed it for a future career. The initial
reasons given for not choosing physics again mirrored those given in the
questionnaire i.e. they were not going to choose physics because it was not
interesting, it was boring, it was not one o f their favourite subjects and they did
not need it for the future.
However, how choices were made and the influences on those choices were
discussed in more detail in all the rounds o f group interviews and a more
complex response emerged. These reasons and influences could be grouped into
themes which are outlined below and discussed in more detail in the rest o f this
chapter.
The first theme discussed is family influences; the influences o f both parents and
other family members. Coming from a scientific family appears to be a major
influencer as to whether to study physics and/or other sciences at A-level. The
influence o f peers is discussed next; how the opinions o f friends play a part, or
do not play a part in influencing choices. Teacher and teaching influences are
discussed next. Within the figured world o f the school, teachers, and the way that
they teach, can have a great influence on whether or not girls choose to study a
subject post 16. These girls live within today’s society. How this society
perceives girls who pursue a study o f physics can influence these girls’ choices.
The belief, held by many in society, that physics is for White, middle class males
and how this belief can impact on choices is discussed. One part o f our identity is
our self efficacy. Previous work has shown a correlation between the level o f self
efficacy and future subject choices. How the girls used self efficacy to influence
choice is one o f the themes discussed. The final theme discussed is the discourse
of achievement. I use discourse o f achievement to refer to the desire to achieve
high grades, that grades are the only thing that matter and that subjects should be
pursued because they will result in achievement o f the highest grades not because
o f interest o f any other reason. A few girls who were not thinking o f choosing
160
physics commented that they would change their minds if they turned out to very
good at it - choices linked to grades rather than interest.
if I all o f a sudden turned out to be a genius in physics (I would choose it)
Margery, Browning School, Y10, No group
One consequence o f the discourse o f achievement, when combined with a belief
that physics is hard, may be to lead girls not to choose A-level physics.
Influences
Four factors that influence subject choices are discussed in this section. Each o f
these influences is not stand alone; they work together. Within a developing
identification with physics and looking at how this identification affects choice,
these influences are part o f the story; they all combine to contribute to identity
work.
Family influences
Many o f the girls talked about how their family and especially their parents had
an influence on their choices. Parental career or interests influenced the girls.
Those girls who reported at least one parent with a scientific career felt their
parents were more likely to encourage them to study science as well.
Examples are:
my dad’s like an engineer, he is always trying to push science instead o f
anything else
Elizabeth, Hinton School, Y9, Yes group
161
my parents would like me to choose science cos my mum is like a vet and
she did all the sciences for A-level
Rose, Hinton School, Y10, Yes mixed group
Many girls, however, reported that their parents, irrespective o f their background,
were not encouraging them towards certain subjects but were just encouraging
them to choose what they wanted. They were being supportive without direction.
my parents don’t really mind what I pick, I think they know what makes
me happy
Lola, Browning School, Y10, No group
my mum doesn’t really like push me to pick a certain sort o f profession
or certain area to do, she just wants me to do, if you get the best that you
can get, in your subjects you are best at
Scout, Hinton School, Y9, No Physics, Yes Science group
Influences by other members o f the family depended on whether the participant
had older siblings or not. Older siblings who had been successful or not in certain
subjects had an impact on subject choice, both to do the same as them (for
example, Florence) and to do the opposite o f them (for example, Kate).
I am influenced by my brothers... .they are a lot older than me they
did maths and physics and one o f them is doing software development
and it interested me
Florence, Browning School, year 10, Yes group
my brother’s doing mathematics, further mathematics, physics and
chemistry and I wouldn’t want to do that
Kate, Browning School, year 10, No group (choosing biology, Russian and
geography)
Within the figured world o f the family, support for future choices from parents
and family members can be a major influence. From their way o f talking in the
162
interviews all the girls appeared to feel confident in making their choices,
whatever the subject, when supported by their parents in that choice. What was
noticeable was that among the girls who had originally expressed that they were
thinking o f choosing physics for further study, 12 o f them reported that at least
one parent had a scientific background. Of the girls who were thinking o f
studying other sciences further, another five reported that they had parents with a
scientific background. Girls who were not thinking o f studying any sciences did
not talk about their parental backgrounds, even though many did mention that
their parents were supportive o f their subject choices.
That parents with a scientific background are also encouraging their daughters to
choose science confirms the findings o f Gilbert and Clavert (2003) that showed
that women in science had chosen that career because o f encouragement from
their parents. Similarly, Olitsky (2006) found that students who had parents who
were scientists identified with the scientific discourses used in the classroom
more than those who did not. These children encountered scientific language
within the figured world o f the family and so it formed a familiar part o f their
world as compared to children who did not have this everyday, home exposure to
scientific language. The fact that those girls who were not thinking o f choosing
physics or other sciences also did not mention that they encountered science in
the home (because they did not mention that they had parents who were
scientists) could mean that a choice to study science was too much o f a move
away from the world that they knew within their family for them to make this
leap. Therefore, could it be suggested that future scientists will only come from
those families where science already forms part o f the family’s figured world?
Further evidence o f where the background o f the wider family influences choices
came from discussions about how brothers and sisters also influenced choice.
However, for siblings, the evidence was polarised; either they wanted to do the
same as their siblings or they wanted to do the opposite. Holmegaard et al.
(2012) mention this conflict between students wanting to make a choice for
themselves and wanting to make a choice that is meaningful to their families. For
the girls in my project who were going to choose to study physics or science, the
influence o f their parents was more than the influence o f their siblings; they
163
wanted to make a choice that was not only meaningful to them but also
meaningful to their parents whether or not this coincided with their siblings
choices or not. For the majority of the girls, their ability to choose subjects that
were both meaningful to them and meaningful to their parents was supported by
them feeling that their parents would support them to make choices that they
were happy with.
Peer influences
As teenagers, peer groups can be particularly important to how one’s identity
develops. As identity develops within a social world we become very aware o f
how we are seen by other people. Some o f the girls felt that their peers offered
them support over their choices, and the majority of the girls in the group
interviews, irrespective o f what subjects they were thinking o f choosing,
recognised that although the peer group may not have a big influence on their
future choices, the support o f the peer group for those choices was important.
they can understand that if you don’t enjoy it you’re not going to (choose
it)
Kathy, Browning School, Y9, Yes group
Many o f the girls talked about how they did not feel that they were influenced by
their friends. They did not feel that they had to choose the same subjects as their
friends and they did not feel that their friends’ attitudes towards their choices
affected them with that choice.
I don’t think friends affect you that much
Ivy, Browning School, Y9, No Physics, No Science group
I’m a very like individual person, I don’t let people tell me what to do, so
if my friends do physics I say great for them
Lola, Browning School, Y10, No group
164
I don’t think it really has an impact on what you want to do if your
friends are like, oh you should definitely do this, well I don’t enjoy it, I’m
not good at it, it’s not going to help me anywhere in life, so what’s the
point exactly
Margery, Browning School, Y10, No group
However, a few o f the girls in year 9 did feel that their friends influenced their
choices, or that other people were influenced by their friends.
all my friends were doing it and it influenced me too
Louise, Browning School, Y9, No Physics, Yes Science group
I think some o f them are there just ‘cos their friends are doing it
Ruth, Hinton School, Y9, No Physics, No Science group
This group o f year 9 girls were more conscious o f how other people saw them or
felt that they needed to be with their friends for the support that they offered. In
their work in the US, Stake and Nickens (2005) found that girls reported less
peer support for their science choices than boys. This work does not allow for the
comparison between girls and boys but does indicate that the majority o f this
group o f girls (White, middle class) did feel that they had the support o f their
peers to pursue the choices that they wanted and that this support was valued by
them. For this group o f girls, peer influences were not as important as has been
previously reported. A small number o f year 9 girls, however, did report that they
were influenced by their friends and peers and that they only felt comfortable
choosing subjects that their friends were doing too; or they recognised that others
in their peer group had made their choices in this way. No girls in year 10 made
this type o f comment.
Support from the wider peer group may have been more variable, as will be
discussed in the section about wider social influences. What the girls did talk
about more was whether they felt pressured to make the same choices as their
friends or not. This again resonates with Holmegaard et al’s. (2012) comments
about students making meaningful choices for themselves. Most o f the girls felt
165
that they were free to make their own choices with support from their parents for
these choices.
As we carry out identity work, we come to think we know who we are and who
others think we are. The development to becoming less reliant on ‘doing the
same as others’ is an indication o f identity work in progress. This identity work
is an individual process. Making choices is part o f identity work. A small number
of girls talked about how they felt their choices were influenced by their friends
and these girls were all in year 9. It could be suggested that making these choices
at a time when some girls are more influenced by what others think o f them, at a
time when they feel more comfortable doing the same as others (their friends and
peers), is the wrong time to make choices that could impact on their whole future
lives. I speculate that the discussion o f this by year 9 girls is due to their age and
that at this age they are more conscious o f how other people see them. This could
also be a ‘comfort thing’. Being with your friends means that you do not stand
out as a different sort o f person from the crowd. Your identity is part o f the wider
social identity o f the many. There is not enough data here to confirm or deny
these speculations.
Teacher influences
Within the figured world o f the school, a figured world that all the girls
encountered on a day to day basis and one that played a major part in their
overall life world at this time, teachers have a dominant role. The influence o f
teachers on subject choices is to be expected and that influence was discussed in
the group interviews. The main discussion theme for the second round o f
interviews was teachers and teaching, but the girls talked about teachers and
teaching in all the interviews. Talk from all o f the interviews was used to look at
how teachers and teaching played a part in influencing choice and identity
development. Much previous work has looked at how teachers and teaching
influence students’ attitudes to science and physics (see Chapter 2) and how
teachers play a role in developing figured worlds where science and physics
identities can develop (see Chapter 3).
166
The comments ranged from girls saying that they felt their teachers had a large
influence on their future subject choices to those saying that they tried not to let
teachers have an influence on those choices at all.
I think choices often are teacher dependent
Charlotte, Hinton School, Y10, Yes mixed group
I don’t really let the teacher influence me that much
Monica, Browning School, Y9, Yes group
Since teachers are such a large part o f the figured world o f schools, the girls went
on to explain this whole range o f influence in more detail. Many famous
scientists who are interviewed about the reasons they chose to pursue a career in
science mention an inspirational teacher who encouraged them to follow an
interest in that subject. This point was discussed during the interviews by year 10
pupils. At both schools, year 10 was when the sciences and other subjects started
to be taught in separate classes. In year 10 the girls would be more aware o f
physics as a separate subject rather than one just mixed in with the other
sciences. It is not only the teacher’s enthusiasm for the subject that can influence
students’ liking o f their subject but how that teacher interacts with the students
(Osborne and Collins, 2001; Krogh and Thomsen, 2005).
I think, like, whenever you get a really good teacher, it is just sparks your
interest in that subject and so that’s probably why I feel myself being
drawn towards those subjects
Skye, Hinton School, Y10, No group
if you really like your teachers and they make that subject really
interesting, like not boring, then you do tend to enjoy the subject more
Alison, Browning School, Y 10, Yes group
Of course the opposite can be said for teachers who pupils consider to be poor
teachers or who they experience as making their subject boring, a common
reason given for not liking science (Osborne and Collins, 2001). This was
167
highlighted by year 9 pupils at both schools. In year 9 pupils are thinking about
what options they are going to choose for GCSE (where they can choose a
limited number o f subjects alongside the compulsory subjects) and so having a
poor teaching experience can influence that future choice.
if you have a really, really awful teacher then you are not going to want to
pick that subject
Joey, Browning School, Y9, No Physics, No Science group
if you don’t like the teacher, then you are not really going to bother (with
that subject)
Doris, Hinton School, Y9, No Physics, No Science group
How much an individual teacher can influence a student’s decision as to whether
to pursue a study of that subject further was clearly reported by Annie.
if I got a bad physics teacher at GCSE then it would probably say
whether I would do it for A-level or not
Annie, Hinton School, Y9, Yes group
She very clearly states a relationship between subject choice and the individual
teacher. At the moment in year 9 when Annie completed the questionnaire she
was thinking o f choosing to study physics for A-level (hence being placed in the
Yes group for the interviews), but she would change this decision based on the
teacher who taught her for GCSE. (The above quote comes from the first group
interview when she was still in year 9 and did not know who her physics teacher
would be in year 10 for GCSE).
At the opposite end o f the spectrum, and falling into a grouping who were
concerned not to let teachers influence their subject choices, is Samantha.
168
I try and remember that I may only have that teacher for a year, and I try
and put them aside and see do I actually enjoy it, even though my teacher
doesn’t make it that interesting
Samantha, Hinton School, Y9, No Physics, Yes science group
Here it can be seen that Samantha is trying hard to detach her enjoyment o f a
subject and her possible future choice to study that subject, from the individual
teacher. This is a hard process as school and teachers are the main source o f
information about a subject. Samantha is attempting to distance the teacher from
the subject and realise that long term enjoyment o f a subject is due to more than
just one person’s influence.
Choice models o f Eccles et al. (1983) and Boe (2012) place enjoyment as one of
the main factors contributing to future subject choice. The girls here described
how a ‘good’ teacher could increase enjoyment o f a subject and how a ‘poor’
teacher could lessen their enjoyment o f a subject. Whatever the subject, girls
talked about how much the teacher influenced their enjoyment o f that subject and
so their future choices to study that subject further. Some girls mentioned how
they tried not to allow teachers to influence them since they may only be taught
by that teacher for a short time.
The notion o f what makes a ‘good’ teacher and what makes a ‘poor’ teacher was
not fully explored. Previous research has focused on the types o f teaching
techniques that physics teachers should use in the classroom to make their
lessons more engaging (for example Angell et al., 2004 and Ladubbe et al.,
2000). The girls did touch on this, but the responses were very variable.
Personal interactions between the teacher and the students can also influence
subject choice. Work by Wubbels and Brekelmans (1997) showed that those
science teachers who took an interest in their students as people reported those
students had a better attitude towards science. The interviewed girls reported that
if they liked their teachers, they were more likely to enjoy the subject that teacher
taught. Interactions with teachers were also reported when the girls described the
giving o f feedback, discussed below in the section on self efficacy. Here they felt
that if the teacher liked you because your work was good, then the feedback
169
received was more meaningful. Also, if the teacher gave praise, this made the
students feel better about themselves. Teachers who pushed students into
answering questions when they did not know the answer or who reported student
test grades to the whole class were described as intimidating and those whom the
students did not like.
Previous research has also focused on how teachers can make the figured world
of the science classroom more conducive to students developing positive science
identities (for example Tan and Calabrese Barton, 2009a and Shanahan and
Niewswandt, 2010). One factor related to how well a teacher can make the
subject they teach enjoyable is the specialism o f that teacher.
The lack o f teachers with specialist science degrees, in particular physics, has
been identified by the Institute o f Physics (IOP, 2012) as a concern in some
schools. Some o f the year 9 girls at Browning School discussed how their
experiences o f being taught by non subject specialists impacted on their
enjoyment o f that subject and could have an impact on their possible future
choices.
our teacher he really likes biology and he’s got to a biology topic and he’s
like, ooh all about it, but when we are learning physics, it was just like
learn this, you’ve got an exam coming up
Ivy, Browning School, Y9, No Physics, No Science group
Ivy reflects that the teacher’s lack o f interest in physics, as compared to biology,
is being picked up by the students and this in turn makes them think that physics
is less interesting. Another aspect o f specialism was voiced by Joey.
He’s specialised in the subject, he knows more, so we can ask him more
questions
Joey, Browning School, Y9, No Physics, No Science group
Here, knowing that their teacher specialised in a certain area o f science meant
that Joey felt that she could ask more in depth questions. By implication, if the
170
teacher has expressed a lack o f specialism, then this type o f question cannot be
asked and more in depth knowledge cannot be passed on.
There may, however, be other issues, less to do with the actual quality and extent
of the individual teacher’s subject knowledge and more to do with how that
teacher positions themselves with respect to their subject specialism. This was
expressed in another o f the year 9 groups at Browning School where Monica also
discussed the issues o f teacher subject specialism.
the best science teacher I have had at this school was the teacher we had
in year 7, um I never knew whether he was a biologist, a chemist or a
physicist, he just didn’t say, he would just teach about everything,
whereas all the other teachers were like, oh I don’t know how to do that,
I’m a biologist
Monica, Browning School, Y9, Yes group
Monica’s year 7 teacher did not tell the class which o f the science subjects he felt
he specialised in compared with other science teachers she had been taught by.
Not knowing his specialism did not impact on her enjoyment o f any o f the
sciences because she felt that he was able to teach all o f them to a high standard.
However, as soon as another teacher said ‘I don’t know how to do that, I am a
biologist’ this introduced a negativity that was picked up on by the students.
These girls felt that when a teacher declared that they were teaching a subject
that they did not feel comfortable with themselves that the message was that they
(the teacher) could not make it interesting and enjoyable and perhaps that the
teacher did not value the subject, so therefore the girls would not and should not
find the subject enjoyable either. For these girls it was not just an issue o f
perceived lack o f subject knowledge (because the teacher had said that they were
not a specialist in that subject) but also how the teachers themselves interacted
with the subject being taught that influenced how the girls felt about that subject.
The girls want to be taught by a teacher who has knowledge, but who also
demonstrates an enthusiasm for the subject being taught. If the teacher does not
demonstrate a negativity to the subject by declaring that they are themselves not
171
interested in the subject because they are not a specialist, or that the knowledge is
only needed in order to pass the test, but instead is positive about the subject and
demonstrate that they enjoy it, the girls will pick up on this positivity and
respond well to both the teacher and the subject. Negativity will also be picked
up and this in turn will have a negative effect on the students. Therefore, it is not
just an issue o f subject specialism, but how the teacher portrays their attitude to a
subject that is important for students’ enjoyment o f the subject. This is an aspect
o f the teacher’s identity; they are not expressing an identification with science as
a whole, but with one (or two) areas o f science. This would not be an issue if that
teacher only taught the subject that they demonstrated a positive identification
with, but, as illustrated above, this is not always the case.
Influence o f society
One o f the questions asked in the third round o f group interviews was about how
the girls perceived what society in general thought about physics and the issue o f
gender equality in the sciences and how this affected their thoughts. The girls
recognised that many people in society held stereotypical views about girls and
science and about other subjects and careers that were typically thought o f as
male or female. A similar image is ascribed to mathematics and Mendick (2003)
discussed how this gendered discourse made it problematic for girls to identify in
any simple way with the subject and so to choose to study it post-16.
General comments were made about these issues; for example, about the
generally held view that subjects can be categorised by gender. The girls
recognised that these views were held but did not endorse them; they felt that
subjects do not have a gender.
it is just stereotyping, yes there are some subjects that go better with
males than females, but if you actually think about it, it is no
Alison, Browning School, Y10, Yes group
172
because o f stereotyping into other subjects, like girls are expected to take
textiles and art and I am not, it is just a generalisation
Margery, Browning School, Y10, No group
They recognised that many in society did still hold a stereotypical view that
physics was for White, middle class males even if it was not admitted.
generally, like, it is still there, even though we don’t want to say it, but it
is definitely still there
Kathy, Browning School, Y9, Yes group
They also recognised that this view had arisen historically in times when women
did not have equal rights with men but that this was changing.
there is a lot o f history coming in here, like women’s rights weren’t as
much.. ..all men who were engineers and stuff. we have got the
message
Indiana, Hinton School, Y10, No group
As quoted above the girls were able to talk about stereotypical views o f gendered
subjects and mainly felt that it was a historical view and not one that they held.
They were reflecting that being a ‘modem girl’ did not fit with them holding
historical, gendered views o f subjects. If they did mention these views and
thought that it reflected that they held them as well, they usually corrected
themselves by adding a statement like ‘I don’t mean that for me’. Baker and
Leary (2003) reported that girls they interviewed also made these kinds o f ‘slips’.
Generally the girls felt that things needed to change and that they were starting to
change, but that this change was slow and generational. They were starting to see
changes in how they and other members o f society perceived the link between
gender and subjects and careers. Joey and Ivy, both from Browning School and
in year 9 when the research started and both not thinking o f choosing physics or
any other sciences, clearly expressed this in their comments which reflected the
173
general view. (Due to group formation, these girls were in different groups for
the interviews even though they were both not thinking o f choosing physics).
Joey said:
I think it is changing, cos like how little kids, like when they are younger,
so stereotypically it would be like the boys would like dinosaurs and
space and things and girls would like dolls and things, I think things are
changing
I think things are changing cos boys still do like physics, but and girls
sort of, you start to get like a split not just between boys and girls, but
between ones that like it and ones that don’t
Ivy said:
most o f the teachers will probably, were in a world, in a society when
girls weren’t there meant to do it like that, and I think they have kept hold
o f that really cos they have grown up with it
but I think it has changed dramatically in the last like 10 or 20 years or
something like that, I think it has changed, but I don’t think it is ever
going to go away
I have never going to an activity and not been asked to do it cos I’m a girl
there are now more jobs available for girls, like, to do what you want and
to engineering and things like that
I think women have just learnt that they are capable and have got more
confident in things and just ignore men
Girls at Hinton School also mainly thought the world was changing as illustrated
by the following extract from the year 9 Yes group.
174
Int30
Summer
Phoebe
Elizabeth
Phoebe
Josie
OK we sort o f touched on Phoebe said quite a bit about
she thinks the subjects are boys’ subjects and some are
girls subjects do you think that still holds true or do you
think that things are changing
changing
I think it is still
I think it is still starting to change sort of
I think it is when you see more girls in uni
I think it is like in year 7 you see divide against divide and
then when you are off to university I don’t think that it
matters the you are into your subject then that is when it
gets better in your class that is just what I think
These examples illustrate how the girls did think that attitudes towards physics
by society in general were starting to change. However, they recognised that this
was a long and slow process that might never be completely overcome. They
recognised that these views were based on historical, generalised stereotypes.
They described how attitudes towards girls doing activities that had previously
been described as ‘for boys’ were changing. They described that as more women
were seen to have careers in physics and engineering then the next generation o f
girls would see these as ‘more acceptable’ careers to aspire to. They recognised
that these changes had been taking place over the past years and would continue
to do so but that change was a slow process.
The girls felt that the changes were being made at the primary age and gave
examples o f this. These views could be a reflection o f the fact that the majority
o f the girls interviewed were from the middle class; Archer et al. (2012), working
with mainly working class primary school children, found that girls aged 10/11
had already constructed the view that science careers were masculine and
incompatible to their feminine identities. Reay (2001), also working in a primary
classroom, found that girls even at this young age grouped themselves based on
their developing identities. These identities were based on old lessons of gender
30 Int is the abbreviation I use to describe my part in the group interviews.
175
relations where it was ‘better to be a boy’ but also contributed to by class,
ethnicity and emerging sexualities. The girls could be grouped, and often
described themselves or others, as nice girls (girls who demonstrate conventional
femininity and were hardworking and well behaved), girlies (emphasised
femininity by maintaining conventional heterosexual acts such as flirting and
discussion about who was going out with who), spice girls (demonstrated ‘girl
power’ by making bids for social power) or tomboys (rejection o f femininity)
although movement between the groups was observed. The ‘nice girls’ were
mainly found to be middle class with working class girls being either ‘girlies’ or
‘spice girls’. Separating themselves into these groups, mainly along class lines,
means that there is only a limited space for girls who reject conforming to
stereotypical gendered norms to inhabit. As mentioned in Chapter 3, many
teachers feel that a good science student is one who is hard working and ‘nice’.
However, if nice girls conform to standard ideals of femininity this produces
identity conflict if they are interested in a subject that is perceived as masculine,
e.g. physics.
Linked to these discussions about society in general and the girls themselves
holding stereotypical views about genders and subjects and careers was a more
specific discussion about physics as a masculine subject and the gendering o f
school subjects in general. The girls expressed views at both ends o f the
spectrum; agreeing that physics and other subjects could be classified as
masculine and disagreeing that any subjects had a gender attached to them. This
is an example o f where the girls could talk about being free to do what they
wanted and not be pressured by stereotypical views o f society as far as careers
and what they wanted to study but still hold stereotypical views about the
gendering o f subjects.
I would say physics and like business are quite manly, whereas
something like art and textiles are feminine
Liwy, Browning School, Y10 Yes group
176
I don’t see physics as a masculine subject, it’s not really, it’s just a
subject, it doesn’t have a gender no subject to me seems
predominantly a certain gender
Delila, Browning SchoolYlO, Yes group
So Liwy, who is thinking o f choosing physics, would agree that physics is
perceived as a masculine subject whereas Delila who is also thinking o f choosing
physics does not think that any subject can be classified in this way. This just
shows how complex this issue is with even those who are thinking o f choosing
physics quite happy to categorise it as a masculine subject and not allow this to
affect their choice. It was not just girls who were thinking o f choosing physics
who thought that it was not gendered.
I don’t think it (physics) is a masculine subject, I think it is open to all
genders
Doris, Hinton School, No Physics, No Science group
However, girls are still not choosing to study those subjects traditionally
classified as masculine even when they now think that subjects should not be
classified in this way.
The work of the ASPIRES project (Archer et al. 2013) found that stereotypical
images o f scientists and what subjects were for boys and which for girls were
formed at an early age and that many parents supported this stereotypical image
and reinforced it. Messages from parents are important as children are growing
up. It is interesting to note here again that the majority o f the Yes girls came
from families who had scientific backgrounds so the images o f scientists being
portrayed to these girls by their parents would have been more positive.
Early exposure to science and parental reinforcement o f the view that science is
for boys was recognised by the girls, several o f who made similar comments to
Joey about boys experiencing science and physics stuff at early ages. The
argument that boys think themselves that physics is for them and that they are
177
better than girls at science, especially physics, was succinctly expressed by
Sunnva.
I think there is always that thing that boys think boys are better than girls
within science, as a whole in physics, I would say that is probably the
strongest one for that
Sunnva, Hinton School, Y10, Yes science group
Another stereotypical view held about physics by many in society is that women
who study it, because it is viewed as a masculine subject, are more masculine, or
have a reduced femininity. Emily, from Hinton School, was one o f the few girls
who was definitely going to study physics at A-level. (Most o f the girls who on
their questionnaire said that they were thinking o f choosing physics did not
continue to think this as the interviews progressed). In her group (who were the
Hinton School year 10 Yes science group) we talked about this aspect o f physics.
Int so Emily you are thinking o f doing physics does that make
you any less o f a woman
Emily I don’t think it does I don’t think it does but
Sunnva I don’t think it does I think it makes you a bit more I want
to say like almost more independent it sounds really stupid
but that’s what I automatically think you see a woman and
then in a mainly male dominated you know subject and I
think it makes a woman seem a bit more powerful and
independent I don’t think any more masculine but you
know I think it your gender is more obvious in a physics
class if that makes sense
Emily especially as some o f the boys seem to be more noisier and
we stand out more if you are seen as a woman in that type
o f profession you are sort o f showing that you can stand
up for yourself
Moa I don’t really know I kind o f I don’t think it kind o f makes
you less o f a woman but I don’t know I didn’t choose
178
physics cos I didn’t think I would enjoy it I didn’t base it
on gender
Emily does not feel that studying physics has any impact on her femininity and
also feels that being a woman in a male dominated area gives her power as she
stands out from the crowd. Her identification with physics is part o f her overall
identity work to come to understand what type o f person she is.
Mendick’s (2003) work looking at post 16 mathematics choices also
demonstrates that girls often do not choose to study mathematics because it is
seen that a choice to study mathematics is a choice to ‘do masculinity’. Choices
are part o f identity work, so choosing to study a subject considered to be
masculine is making a choice to do masculinity as part o f your identity. Based on
society’s views, it is often difficult for girls to make this identity choice, so they
choose not to pursue a study o f a masculine subject. This is very similar to the
choices made around physics. Francis (2010) describes these movements away
from a binary description o f gender as being part of a heteroglossic gender
system where girls can display a macro femininity but with micro masculine
contradictions.
On a final positive note, some o f the girls talked about how successful women
could be if they did choose to study physics; that they should study the subject if
they are good at it and that it was not wrong to study it.
I think women would be good at physics
Sunnva, Hinton School, Y10, Yes science group
I definitely respect a female in physics, no, I wouldn’t think it was wrong
at all
Lola, Browning School, Y10, No group
Generally the girls agreed that there is no problem with girls studying physics or
taking up a career in physics. They recognised that many in society still held
stereotypical views about physics; that it is for White, middle class males.
179
Although the general feeling was that girls can do physics and that society was
changing to accept this view, other voices continued to be expressed; that physics
and other subjects were gendered; and that boys were better at physics than girls
because o f early exposure to the subject at home.
As described at the start o f this section, all these influences play a part in a girl’s
identification with physics. For individuals, one or more o f these influences can
be more important than others and this will vary from individual to individual.
The people who play a part in these influences, parents and family, peers,
teachers and society in general, all need to be aware o f how they can impact on
both a girl’s identification with physics and their future subject and career
choices. Awareness o f the importance o f being an influencer can bring about
change.
Self efficacy
As described in Chapter 3 self efficacy is a person’s self perceived capability for
learning or performing actions at designated levels. Four factors have been
identified as affecting the level o f self efficacy. These are previous performance
(mastery experience); seeing similar others carrying out the action (vicarious
experience); feedback given on the activity (social persuasion) and physiological
states.
In Chapter 3 ,1 also described the link between self efficacy and identity, arguing
that self efficacy was just one component o f identity. Self efficacy has previously
been measured quantitatively, with just a few examples in the literature where
self efficacy has been investigated using interviews (Usher, 2009). During the
interviews I did not directly ask about self efficacy, but I did refer the girls back
to the question they had answered on the questionnaire where they had ranked
their ability in physics relative to their class and their friends and asked them to
discuss this ranking. Many o f the groups also talked about teacher feedback (one
factor predicted to affect self efficacy) when discussing teachers and teaching.
180
Previous performance
The first factor identified in Bandura’s (1982) work (see Chapter 3) as affecting
the level o f self efficacy is previous performance. It has been suggested that a
good performance can increase the level o f self efficacy and make someone more
likely to pursue that activity further. This was the case for the girls.
I think when you get like a test back or something, and you’ve got a good
grade in it, then you feel like you understand it
Sunnva, Hinton School, Y10, Yes science group
when I get something right, it makes me like, someone ask me a question
and I go, I know that answer to that and everyone is like well done
Margery, Browning School, Y10, No group
Achieving high grades in tests confirms that you have understood the work that
was being assessed so gives you more confidence to continue to study that
subject further and increase your self efficacy. Feeling good by achieving good
test results was mentioned by both Yes and No girls as being important.
Margery’s comment describes two o f the factors that Bandura (1982) identified
as affecting levels o f self efficacy. These are firstly her mastery o f a subject, in
that she feels good when she gets something right and that this gives her more
confidence to answer more questions. The second factor is feedback from others
(see below) and that when other people congratulate her on getting something
right it makes her feel good and increases her self efficacy.
Comparison to similar others
The second factor Bandura (1982) identified as having an affect on a person’s
level o f self efficacy was seeing similar others carrying out a task. If these
similar others were successful in that task, then self efficacy is increased based
on the maxim ‘if they can do it, I can too’. At both schools, students were setted
by their previous attainment with the implication that all students in any one set
181
should have a similar ‘ability’ to complete tasks. At both schools the girls
described how seeing others in their set being successful actually had a negative
affect on them; it decreased their self efficacy.
I mean in our lessons, the ones who are really, really bright, that can be a
bit intimidating
Rose, Hinton School, Y10, Yes mixed group
They did not feel that seeing other members o f their set achieving or being able
to answer questions in class as being helpful because they saw them as being
cleverer than them rather than similar.
It makes you feel like you are the only one who doesn’t get it, if you are
in a high set and everyone goes, like I get it
Samantha, Hinton School, Y9, No science group
Related to seeing similar others being successful and not being able to relate to
them was the aspect o f asking questions in class to clarify understanding. The
girls felt that as others in their class already understood the topics being studied,
then asking questions would make them appear less able.
Especially if you are in the highest set, it seems that everyone knows and
understands in physics, it is kind o f you don’t want to ask a question ‘cos
you think that everyone else knows what they are doing
Emily, Hinton School, Y10, Yes science group
As Shunck and Meece (2005) found, classrooms where the emphasis was on
competition and performance goals were ones where self efficacy decreased. The
classrooms described here by the girls, show that competition between students
and seeing similar others achieve more highly than them did in turn decrease
their self efficacy. Competition in the classroom also led to the girls feeling
embarrassed that they did not know an answer to a question when asked, and
anxiety that they would be asked to answer questions when they did not know
the answer. This also weakened the girls self efficacy. This was the same
182
whether the girls were thinking o f choosing physics or not. These classrooms
were not ones where solidarity with each other and collaboration were
encouraged, both aspects identified by Shunck and Meece as being aspects of
classroom management that would increase self efficacy.
A comment from Louise combines both the effect o f mastery (described above)
and comparing yourself to similar others as related to grades achieved in tests.
I really lose confidence when I hear everyone else’s (grade read out)
Louise, Browning School, Y9, No science group
Louise’s comment could imply that her own grade achieved could increase her
self efficacy if it is considered to be a good grade and as long as she did not just
attribute this good grade to luck. The main issue that is decreasing her self
efficacy is when this grade is compared to the similar others in her set (class) and
if many other students have achieved a higher grade than her, then her
confidence and self efficacy decrease.
Feedback
Bandura’s (1982) third factor that affects self efficacy is the feedback given on
an activity. Negative feedback has been reported (Bandura, 1982) as weakening
self efficacy and positive feedback as strengthening it. It was girls who were not
thinking o f taking physics that talked about the need to receive positive feedback
to make them feel that they were on the right track and that they understood the
work being done in the class. When they did receive praise from the teacher, it
made them feel good.
The main giver o f feedback in schools is the teacher. Louise describes how when
the teacher gives positive feedback, praise, it can boost her self efficacy.
183
when she (the teacher) praises one, you feel like you should get it right,
and then when she does and you get it right, you feel really good
Louise. Browning School, Y9, No science group
The teacher can be seen as the gatekeeper to knowledge. Ruth describes how
when a teacher gives you positive feedback, then that feedback has weight to it
as the teacher is the one who knows that the work is good. Getting positive
feedback from a teacher also makes Ruth feel that the teacher will like her more,
another positive feedback factor that will increase her self efficacy.
you kind o f want her (the teacher) to like you and say your work is good,
cos then you know that it really is
Ruth, Hinton School, Y9, No Physics, No Science group
Informal feedback given during the lesson whilst activities are actually being
carried out, rather then once the activity has been completed, can also help to
increase self efficacy. They give an immediate boost and allow the student to
continue with the activity rather than giving up.
Sometimes if you need, like, to be reassured that you are doing it right, it
would be nice if he (the teacher) could come like over and just say, oh
you are doing that right
Samantha, Hinton School, Y9, No science group
Positive feedback from a teacher, either during the lesson or after, can both
increase self efficacy and, since it makes you feel good, reduce the feeling that
this subject is not for you; improve your overall mindset with regards to a
subject. Positive feedback whilst carrying out an activity will also reinforce that
effort to continue carrying out an activity is needed and that this, in turn, since
carrying on with an activity can lead to achievement, will increase self efficacy.
184
Physiological factors
The final factor identified as influencing self efficacy levels (Bandura, 1982) is
physiological states, for example anxiety, stress and moods. Anxiety and
embarrassment were mentioned by the girls and they discussed how this affected
their performance in class and their enjoyment o f the subject.
Being anxious about not having the knowledge to complete a task can reduce self
efficacy. This can also be expressed as not having the confidence to answer
questions, either in class or on tests, because the answer is not known.
I am always anxious that I’m not good
Scout, Hinton School, Y9, No science group
I’m embarrassed because I don’t know the answer
Josie, Hinton School, Y9, Yes group
In the classroom described here the teacher can contribute to a student’s
anxiousness by insisting that they answer questions. If students are unsure o f
their level o f knowledge, the worry that they will have to answer questions and
not be able to provide the correct answer can contribute to levels o f anxiety and
embarrassment and so further reduce self efficacy.
she (the teacher) makes you answer, and you just feel more embarrassed,
and you feel like everyone’s going to laugh at you
Chloe, Browning School, Y9, No science group
Anxiety can also lead to students not being prepared to ask for help when they
don’t understand the topic being studied. This can cause a spiral o f emotions that
lead to the situation becoming more difficult to overcome.
185
Well the more you don’t understand it, the more you switch off, the
worse you get, and then you get too scared to ask, and it just gets worse
and worse and worse
Anya, Hinton School, Y10, No group
Self efficacy and A-level physics choices
Self efficacy is a complex quality that forms one part o f a person’s identity. The
four causal factors identified by Bandura (1982) as contributing to levels o f self
efficacy cannot be described totally in isolation to one another as, with the many
factors that influence identity development, they are interlinked. The quotes
above go some way to illustrating how self efficacy can be affected by
interaction in the classroom, both with teachers and with other students, and how
levels o f self efficacy can fluctuate in a similar way to identity development as
described in identity trajectories in Chapter 3.
As with the four influences described earlier in this Chapter, how much each of
these factors affect self efficacy is an individual thing. Levels o f self efficacy can
fluctuate markedly; for example after achieving a high score in a test self
efficacy can be high but this can be decreased again if the score in the next test is
low. Britner and Pajares (2006) found that self efficacy is a strong predictor for
future subject choice. I propose that this needs to be a sustained high level o f self
efficacy to be directly linked to choice. Since self efficacy is one component o f
identity, understanding how levels o f self efficacy can be affected by Bandura’s
four causal factors is important to understanding how identification with physics
can fluctuate as well. In a classroom situation, the person who has the main
impact on self efficacy is the teacher; so it is important that teachers understand
the overall impact o f self efficacy levels when linked to identity and subject
choice.
186
A discourse of achievement
During the discussion about future subject choices at Hinton School, I identified
what I term a discourse o f achievement when I analysed the text. This discourse
centres on the desire, or the perceived need, to achieve high grades in GCSE
subjects, that grades are the only thing that matter and that subjects should be
pursued because they will result in achievement o f the highest grades not because
of interest or any other reason. This discourse is linked to self efficacy (see
previous section) but the relationship between the two is complex. Self efficacy
describes how one feels about performing in a certain subject whilst the
discourse o f achievement describes the desire and the need to achieve high
grades. This desire to achieve high grades is linked to the messages coming
sometimes from government and society in general that it is only grades that
matter in the future (for example, the Department o f Education’s recent statement
(2013) that every student will achieve a grade C or above in English and
mathematics or they will continue to study them until they do). Subjects are
therefore chosen for future study that will give the easiest path towards achieving
the high grades necessary for progression into higher education and careers.
Some o f the girls discussed how their GCSE grades would influence their future
subject choice. Since the introduction o f the National Curriculum pupils have had
a more limited subject choice at GCSE with most subjects or curriculum areas
being compulsory. It is at A-level that the first major choice o f subjects is made.
Some pupils, in this study, discussed the possibility o f basing this choice on
grades achieved at GCSE as much as enjoyment o f the subject or future career
aspirations.
you want to do well in your A-levels and get good GCSE results, and
then more likely to get better A-level results, so you are more likely to
take those subjects
Doris, Hinton School, Y9, No Physics, No Science group
187
most people do pick what they are good at, ‘cos there’s no point in doing
something that you are not good at, otherwise you are just going to be
wasting your time
Ruth, Hinton School, Y9, No Physics, No Science group
In later discussions at both schools, girls again talked about how they wanted to
achieve good grades in their subjects and about how they felt pressurised to do
so. Young people in today’s society are often categorised by the grades they
achieve in their qualifications. They also describe themselves as being at a
certain level or having a certain number o f GCSE high grade passes. The primary
school children researched by Reay and Wiliam (1999) described how they
classified themselves by the level o f attainment they were working at (in their
case the level they were predicted to achieve in upcoming SATs (Standard
Aptitude Tests)). These primary age children ‘knew’ that they needed to achieve
at a certain level in order to be seen as good, academic, students and in order to
have good future prospects in both education and careers. If they did not feel that
they could achieve the desired levels, they described themselves as ‘being
hopeless’ or ‘being nothing’.
Schools and governments also always want to increase achievement and the
percentage o f pupils who achieve a certain grade in their school examinations.
Not only do the girls want to achieve good grades themselves and then pursue
those subjects where they will be successful, they feel that they are pressurised
by others to achieve good grades. Of course, pressure to succeed can be both
positive and negative.
so much pressure that you get anxious, you get really frightened
Kathy, Browning School, Y9, Yes group
there’s always been quite a bit o f pressure on me to get good grades
Ruby, Hinton School, Y10, No group
188
I am predicted all As, but I can tell you that is not going to happen, it
makes like so stressful
Doris, Hinton School, Y9, No Physics, No Science group
The pressure to do well was exerted by teachers, by family and by the peer
group.
the teachers put so much pressure on you
Ivy, Browning School, Y9, No Physics, No Science group
she (my sister) got A stars and then I feel like pressured to try and get as
good as her
Ethyl, Hinton School pupil, Y9, No Physics, No Science group
it is almost like competitive about exam results in our year, in our
school, is quite competitive and we really want to do well
Anya, Hinton School, Y10, No group
Both schools have an above average GCSE success rate (see Chapter 5 on
schools for details). My impression at both schools was that they encouraged the
pupils to achieve the highest grades possible in all their GCSE subjects. Both
schools ran revision sessions before the examinations using a special timetable.
The achievement o f good grades was a whole school ethos that formed part o f
the figured world o f the school.
The girls described how they felt that the need to achieve good grades was o f
great importance and that this message formed a part o f the whole school ethos at
both schools. In some cases, the requirement to achieve a high grade was seen as
more important than enjoying the subject and the pressure exerted by teachers,
family and peers to achieve highly caused anxiety (see section on self efficacy
above for more discussion about anxiety). The need to achieve good grades also
impacted on future subject choice in that girls felt that they should only choose
subjects where they could easily achieve these good grades. This need to achieve
189
good grades over and above all other considerations forms the basis o f the
discourse o f achievement.
In Boe et al.’s (2012) discussion about using aspects o f the Eccles et al (1983)
choice model they highlight five factors that related to STEM choices. One of
these is expectation o f success. They feel that this is similar to self efficacy but
also related to the fact that the physical sciences are seen as hard. Young people
want to be successful themselves and in order to be successful will choose
subjects that they can see that they will be able to achieve at a high level
predicted by previous success.
The discourse o f achievement differs from Eccles et al’s (1983) expectation o f
success criteria in that it goes further than an expectation to a need to achieve
success at all costs. The discourse o f achievement describes not just a hope, an
expectation or a belief that choosing to study a certain subject will lead to
success, but that there is a need to choose those subjects where success is
guaranteed (as much as it can be) based on previous experience and achievement
and not on interest and enjoyment.
In her work on mathematics (Mendick (2003)) one o f the ways she categorised
students who chose to study mathematics post 16 was those who felt they had
something to prove to themselves or to others. The discourse of achievement is
the opposite o f this. In Mendick’s work, these students chose mathematics
because if they achieved a good grade in a hard subject, this proved, to
themselves sand others, that they were capable o f being successful in a subject
that others considered to be hard. In the discourse o f achievement, no
differentiation is made between the subjects, whether they are considered hard or
soft. All that matters is that the highest possible grade is achieved in any subject.
Three other students in Mendick’s work, who described themselves as being
good at mathematics, chose mathematics because o f this. This could be an aspect
o f choice linked to the discourse o f achievement. However, these students also
described themselves as liking mathematics. The discourse o f achievement
centres on a desire to be successful rather than being interested in or liking
mathematics.
190
Discussing the Multiple Influences
The discussion o f the analysis o f the interview data given above shows how
complicated the issue o f future subject choices is and the many factors that can
influence those choices. In many cases my analysis supports that which has been
previously reported. The girls described how they chose subjects they were
interested in (Boe, 2012) and those that they needed for future careers
(Woolnough, 1994; Pike and Dunne, 2011 and Cleaves, 2005). Students were
influenced by their parents (Sajaastad, 2011), most reporting that their parents
would support them in making the choices that they were happy with. Those girls
who were thinking o f choosing physics reported that they were doing so because
of direct support from parents who had a scientific background (Gilbert and
Calvert, 2003). These girls were also exposed to a family figured world where
scientific language was the norm (Olitsky, 2006) so choosing to study physics or
science was part o f their overall world and did not result in border crossings
(Aikenhead, 1996).
The influence o f peers was not as important for these girls as has been previously
reported (Stake and Nickens, 2005). These girls did not feel, in general, that they
were influenced by their friends in the subject choices they made, but that peer
support for those choices, once they had been made, was important. A small, but
significant, group o f girls who did feel influenced by their friends were all from
year 9.
As has been previously reported (Angel et al., 2004 and Ladubbe et al., 2000) the
teachers whom students consider to be ‘good’ increase enjoyment o f a subject
and this leads to possible future choice. These are teachers who ‘teach with
enthusiasm’ regardless o f their actual subject specialism. One aspect o f teachers
not reported before, but that did have an impact on year 9 girls from Browning
School, was the subject specialism o f the teacher. The impact was not only to do
with the subject knowledge but how the teacher described their own poor
relationship with the subject outside o f their specialism, which was often physics.
When teachers displayed that they themselves did not enjoy the subject they were
191
teaching, this negativity towards that subject was picked up by the girls. The girls
felt that they were not able to discuss in depth topics or ask for help from the
teacher due to a perceived lack o f knowledge, and that they also were not
inspired to enjoy the subject because o f the teacher’s lack o f enjoyment.
However, as one girl described, if the teacher taught with enthusiasm and did not
report that they were teaching out o f their specialism, there was not an issue.
The stereotypical image that physics and physicists are dominated by White,
middle class males is a view that is held by many in society (Ryan, 2011). The
view given by Margery that only Polish women can work in physics shows that
although women have worked in physics by only using Marie Curie as an
example gives a narrow image o f the women who have done so. When
questioned about this stereotypical view, the girls reported that they were aware
o f this but that they felt that changes in society’s view o f what girls could and
could not do for careers and subjects that they could study were changing, albeit
slowly. However, when they talked about this in more depth, many other voices
were present - that physics is still considered to be a subject for boys (Francis,
2000), that girls who study physics are less feminine (Breakwell et al., 2003 and
Cleaves, 2005), and that boys themselves consider that they are better at physics
than girls from an early age (Archer et al., 2013). These conflicting voices were
all heard as part o f the identity work being carried out by the girls in the
interviews.
One o f the reasons given that many students, boys as well as girls, do not choose
to study physics post-16 is that it is considered to be a hard subject (Bennett and
Hogarth, 2009 and Pike and Dunne, 2011). My analysis found that a turther issue
linked to this was what I describe as the discourse o f achievement. The discourse
o f achievement describes the desire to achieve high grades in GCSE subjects,
that grades are the only thing that matter and that subjects should be pursued
because they will result in achievement o f the highest grades not because o f
interest. That physics is considered to be a difficult subject in which to achieve
the high grades needed to be successful in future life was a reason for not
choosing it.
192
I have proposed that self efficacy is one component factor o f identity. Levels o f
self efficacy can fluctuate depending on four causal factors (Bandura, 1982).
When discussing how they felt about physics the girls reported that they felt
better (had a higher self efficacy) when they had achieved good test scores and
when they received positive feedback from their teachers and that their self
efficacy was lowered by poor feedback and when they were anxious. This was as
previously reported (Schuink and Meece, 2005). However, success by
comparison to similar others, in the competitive atmosphere o f the physics
classroom being experienced by the girls, was not something that increased self
efficacy as proposed by Bandura; in fact most girls reported that their self
efficacy was decreased when they compared themselves to the similar others in
their classes.
At the start o f this research, I proposed to investigate how physics identity and
physics self efficacy impact on future subject choices. The literature interrogated
in chapters two and three described a range o f factors that have been found to
influence choice and identity work. These influences (parents and family, peers,
teachers and teaching, and the image o f physics) along with self efficacy (a
component part o f identity) and a discourse o f achievement have all been used as
themes with which to analyse the data gathered during small group interviews
with girls in years 9 and 10 who were both thinking o f choosing physics post-16
and those who were not. Much o f the analysis has supported previous findings
but new factors have also been identified, namely the discourse o f achievement
and the importance o f teacher subject specialism. It was also found that expected
differences between possible choosers and non-choosers, as predicted from the
questionnaire data presented in chapter 5, were not so obvious when discussion
took place. Getting a complete picture o f how physics identity and physics self
efficacy contribute to choice decisions was also not clear when using the group
discussion data. The importance o f these was starting to emerge. Moving towards
a focus on the narratives o f individual girls would, hopefully, give a clearer
picture o f how identity and self efficacy do impact on choice. These individual
narratives are presented in the next Chapter.
193
Chapter 7 Narratives of Identification with
Physics
Introduction
In the previous Chapter, the thematic analysis described how different factors
could influence a girl’s decision to choose or not to choose to study physics post-
16. However, what they did not do is offer a picture o f the complexity o f how
each o f these factors could influence any one girl; how these influences worked
together, or in opposition to each other, to result in how an individual made their
physics choices.
In this Chapter I look at the narratives o f four girls from Hinton School. They
allow a more in depth investigation o f how girls’ identification with physics
develops and changes over time. I use identification to describe every
relationship with physics whether it is a positive identification or a negative
identification sometimes termed a dis-identifcation. These narratives are o f
course not generalisable. They are constructions about specific girls who are
learning about themselves and developing their identities and their identification
with physics during their secondary school years. However, I believe that these
narratives will be familiar to us, at least those o f us whose own experience o f
education is in the UK. We will recognise in the narratives girls whom we know
or, if we have been teachers, whom we may have taught; and we may even
recognise ourselves, or aspects o f ourselves, in their narratives too.
Each narrative looks at one particular girl’s journey towards making a choice as
to whether to study or not to study physics post-16. They look at how the
influencing factors discussed thematically in the last chapter come together in
that individual’s identification with physics and how they impact on the choices
made. Before presenting the narratives I build on the discussion in Chapter 4 to
194
describe in more detail the interview process and analysis that resulted in the
narratives.
Interview processes and analysis
It was whilst I was carrying out the second round of group interviews that I
started to notice that some o f the girls involved had individual narratives that
seemed to vividly illustrate how girls develop an identification with physics and
how they interact with the figured world o f science in general and physics in
particular. After completing the third round o f group interviews, I used NVIVO
to collate all the quotes made by individual girls from each o f the three group
interviews. Using these collations and a simple spreadsheet (see Chapter 4), I
identified five girls whose narratives appeared to me to describe key different
ways that identifications with physics develop and change over time.
They were all girls from Hinton School. This outcome was unexpected. When I
had collated the information from each o f the three rounds o f group interviews
for each individual girl onto the spreadsheet described in Chapter 4 ,1 hid the
columns showing name, school and year group before I made my selection.
When I discovered that all the girls came from the same school, I questioned this
outcome. This was not a conscious choice on my part, but did my subconscious
come into play? I did not choose girls from Hinton School because it was nearer
to my home (I enjoyed my trips to another part o f the country when I visited the
other school), nor because these girls were easy to access (in fact it took over a
term once the choice had been made before I was able to interview the girls
again). By the time I made this choice, I was immersed in my data and knew the
individual girls well and so, therefore, I may have made an unconscious choice.
However, if this was an unconscious choice it was not for any obvious reason,
for example, I did not feel that I chose these girls because I felt that I could talk
to them easily (I would say that there were other girls at both schools with whom
I had built up a better rapport). The fact that all these girls came from the same
school could be just that these girls were able to articulate about their
195
relationship with physics more than other girls either from the same school or
from a different school. The school they attended could be an influencing factor
to them having more to say but this would need to be investigated further in
order to draw this conclusion. All I can say is that this was not an intentional
choice.
I approached four o f the identified girls by letter and asked them to take part in
individual one to one interviews. They all agreed to be interviewed, but only
three o f them attended the interviews on the designated day. For the fifth girl, I
felt that talking to her again might be too painful and so ethically I did not feel
that this would be o f benefit; I already had enough detail to write her narrative.
Three o f the narratives tell o f girls who at some time during their journeys
towards A-level choices thought that they would choose physics. At the time o f
their individual interviews, I already knew that they were not going to choose
physics, even though they were all capable o f doing so and had thought about it
at some point. In fact none o f them did and their narratives look at why. The
fourth girl indicated on her questionnaire that she was not thinking o f choosing
physics but was thinking o f choosing other sciences. At the time o f her
individual interview, she had still not made her final A-level choices.
These four narratives are described and discussed below. I start with Rose, who
by the time she made her final A-level choices was focused on the subjects she
would need to progress to her chosen career. These did not include physics, even
thought she was a very capable physics student. The next narrative tells o f
Indiana’s relationship with physics and how one incident greatly impacted on her
identification with physics. Charlotte’s story describes a girl who, in some ways,
‘ticks all the boxes’ about what a good physics students should be but she still
did not choose to study A-level physics because she enjoyed other subjects more.
The final narrative is that o f Scout. I’m still not sure how to fully describe
Scout’s relationship with physics (or science). Her’s is the most complex story.
196
Rose
Rose was a year 10 pupil at Hinton School when I first met her. On her
questionnaire she indicated that she was thinking o f taking A-level physics along
with history, French and chemistry so I selected her as part o f the Yes mixed
group31. On her questionnaire her reasons for thinking about choosing physics
were that she was interested in a career in science but had at that time not
decided what she wanted to study, but since physics and chemistry were her best
sciences she was considering them both. Her reasons for choosing history were
that she enjoyed it and that it would be a break from the work o f her other A-
levels and for French that she wanted to live in France in the future.
When asked to select words that described how she felt about physics Rose chose
‘enjoy’, ‘like’ and ‘interesting’. She felt that she was about the same ability as
most people for physics but that she enjoyed it more than her friends. She
thought that she might be a physics sort o f person because ‘I enjoy physics and
am not too bad at it’.
Rose described herself as being White and both her parents as being professional.
During the interviews she said that her ‘mum’ was a vet and that she had taken
all sciences for A-level and that her ‘dad’ now worked in environmental
engineering working especially with flood defences. She talked about how she
had lived in the countryside when she was younger and spent a lot o f time
playing with her three brothers and their friends. When I asked the girls to
describe themselves in the third group interviews Rose described herself as
energetic, generally bubbly and as caring a lot about things and people. She felt
that in school she wanted to please all her teachers and worked really hard in
order to do this
At the start o f the group interviews Rose was just completing year 10. By the
time I interviewed her individually she had just completed the first term o f her
31 Yes mixed group - girls who are thinking of choosing physics as part of a mixed A-level programme
197
AS year (year 12). Over the five terms that I got to know Rose, she matured into
a very confident young woman. She always came to the interviews willing to
participate fully and spoke in a clear, articulate manner. She often wore large
flower clips in her longish blond hair. At the final interview, where as a sixth
former she did not have to wear school uniform, she wore up-to-date, stylish and
feminine clothes. This could be interpreted as Rose performing popular
heterofemininity to balance out her scientist aspirations as Archer et al. (2012)
saw in their 11-12 year old girls. This is a performance to become accepted by
her peers who may have little or no interest in science and see girls who do have
an interest in science as being less feminine than them (Breakwell et al., 2003).
Performing, or even over performing, highly feminine traits, such as the
fashionable cloths and hair ornaments, can help to balance out the perceived drop
in femininity due to her interest in science.
Rose’s initial focus on choosing A-level subjects was to meet her aspiration to
have a future career in science. In the first group interview she was fairly vague
about what science career she wanted, although she did know that she wanted a
career in science whatever the role was.
maybe chemistry cos I quite like science and I feel like I want to do a
science at least at sixth form and chemistry or physics, they are my best
two sciences................ I would quite like to be a scientist. I’m not really
sure; I change all the time what I want to do but at the moment I want to
be a I would quite like to do some form of science
Group interview one
By the time o f her individual interview, Rose had chosen her A-levels around the
fact that she wanted to go on and study medicine. For her A-levels she had
chosen mathematics, chemistry, biology and French. Rose was very successful in$
her GCSEs gaining 8 A and 2 As. She felt that the main influence on her subject
choices was her future career.
198
to do with what I want to go on and do in the future because I had to do
three sciences o f some description
Individual interview
Rose explained that one o f her reasons for choosing subjects for a certain career
was to do with future security.
I think so because we have a lot o f pressure put on us and quite a lot of
people worry us about what you are going to do in the future, and I think
it is, it’s just something that is always niggling, you want, you don’t want
to study a course when you don’t know what is going to happen
afterwards
Individual interview
This focus on careers was one o f the reasons that Rose felt people, and girls in
particular, did not choose to continue to study physics.
I think one o f the main reasons that people aren’t choosing physics, I
think a lot o f people who have got career focuses it is the obvious careers,
for example medicine or law or business, that seems to be the people who
I know have got clear focuses on what they want to do, they all seem
those kind o f focuses, whereas people who don’t have focuses they don’t,
they, yeah they could be more interested in just looking at science
generally, but I think that if you knew from physics that there were
certain jobs that you could get I think that is the worry that people don’t
really want to study physics and go on to study physics ‘cos they don’t
know that there is definitely a job for them out there, what kind o f jobs
they might get with a physics degree, but if they knew what kind o f jobs
they could get, look at the employability o f people who have studied
physics, I think that would definitely increase the amount o f people who
want to do it because a lot o f people want to do medicine, law and things
‘cos they know if they do get onto those courses then afterwards they
have fairly guaranteed jobs, particularly medicine
Individual interview
199
Rose’s A-level choices were closely linked to her future career aspirations. This
was also demonstrated by students in Pike and Dunne’s (2011) study who made
it clear that their future subject choices were linked to careers. This was also an
aspect o f Boe et al.’s (2011) work where they linked choices with the utility
value o f a subject.
At the start o f the interview process Rose had not decided on a career, just
something in science, so was considering chemistry and physics, her two best
science subjects, alongside French and history. By the time o f her final interview,
Rose had decided that she wanted to study medicine. To do this she needed to
take three science subjects and had chosen chemistry, biology and mathematics
but not physics. She explained that she found chemistry and biology easier than
physics because she felt they came more naturally to her. Talking to her it
appeared that she felt that she would be able to gain top grades for these subjects
at A-level and so be successful in gaining a place to study medicine; the
influences o f the discourse o f achievement on the subjects she chose to study
post-16. (Universities that offer medicine expect entrants to have gained A* or A
grades for their A-levels). Rose gained A* grades at GCSE for mathematics,
chemistry, biology and physics and she told me that the marks for physics were
the second highest o f all her GCSE marks. (The GCSE results sheets give marks
as well as overall grades). From a grade achieved point o f view alone, it could be
suggested that taking A-level physics would have been a good idea. However,
Rose felt that she had had to work hard to achieve this physics grade and that
would not translate into a high A-level grade. Rose here is ‘buying into’ the
commonly held belief that physics is hard (Francis, 2000). Therefore not only is
A-level choice based on future career aspirations, it is also based on the path that
Rose feels will most easily allow her to achieve that goal.
Rose’s relationship with physics was very much linked to her relationship with
her physics teacher and how he taught physics. In the first group interview I
asked the girls what influenced them to choose certain subjects for A-level. One
of the other group members said that she felt that teachers were a big influence
on her choices. She said that she liked physics as a subject but that her teacher,
200
who she felt was not very inspiring, had turned her off physics. Rose then
explained how her teacher had also influenced her relationship with physics.
this year I’ve got like a really good teacher and he’s got me, he’s the one
who’s got me really interested in physics. Last year I kind o f didn’t like
physics at all but this year he’s got really interesting lessons, really
interesting and things like that and he kind o f explains more, such as this
will happen because o f this whereas I didn’t find like last year that I had
that explained to me very well. He makes it really interesting, makes the
lessons like really fim to be in so I really like physics this year
Group interview one
Even though Rose had expressed an interest in taking physics A-level in her
questionnaire she was now not so sure that she would because o f how her
physics teachers had influenced her relationship with physics.
in fact I wouldn’t want to do physics. I would love it if we had the teacher
I’ve got at the moment but if I didn’t, if I didn’t care what teacher I was
going to get, I know if I was going to get some teachers, another teacher
like perhaps I wouldn’t be as interested in physics. I think I was ‘cos I did
struggle with physics last year the only reason I get it this year, like really
been listening and working really hard at physics. I really find the
motivation to do that quite hard if I had a teacher who didn’t explain it
properly for me personally
Group interview one
In the second group interview, Rose still had very positive things to say about her
physics teacher.
I find physics really difficult as a subject but with my teacher, my teacher
is helping my class. They are all, we all work together and help each
other in class and we are encouraged to do that so it is so much easy for
physics. I think we just do that
Group interview two
201
Rose comments positively about how the teacher works in a collaborative
manner with his students. Schunk and Meece (2005) found that self efficacy
increased in classrooms where teaching was in a more collaborative manner,
where there was emphasis on the importance o f effort and where there was
meaningful learning linked to student interests. This is very important for girls,
who often display a lower self efficacy than boys in science (Britner and Pajares,
2006). This is certainly the case for Rose.
Rose went on to describe further aspects o f her physics teacher, in particular how
he interacted with the students on a personal level, that had helped her to engage
with the subject more than previous ones had.
my teacher is kind o f a bit different from theirs, like he is really relaxed
about physics, but he, he does it, he teaches it really well and he is a
really nice kind o f teacher as well, so he is also, he is really good about
being nice to people in the class and he will, he is quite understanding
like about people
Group interview two
the way he teaches is really engaging ‘cos he is really so passionate about
his subject and he is really good about helping each o f us individually
Group interview two
he is really good about giving you extra time or something; he will be
really good about sitting with you and giving you extra help so that you
understand, he is really good
Group interview two
In her individual interview, which was after she had received her GCSE results, I
asked Rose how much she felt her teacher had contributed to her GCSE Physics
success. She felt that he had.
202
he knew that I was worried about my final module ‘cos I wanted a good
grade on my last module, ‘cos I had to get a good mark in order to get my
A star overall and I think he understood that and he was willing to put the
extra time in after school and during lunch times and things. I think that
worked towards me getting my A star............. he knew that what I really
wanted was an A star and he was willing to put the extra time in for me to
get my A star
Individual interview
In the final individual interview I asked Rose if her decision not to study physics,
even though she got her second best GCSE mark for physics, was related to the
teacher o f not. She felt that it was.
I don’t really regret taking any o f my subjects particularly, I think it is a
bit o f a ‘what i f but then, it is the same with the physics, if I had gone
and taken physics at A-level and then not got on with my physics teacher
then I am sure it would really be the same and so it’s hard to kind o f say
whether or not I would have preferred to do a different subject and I think
it is just dependent on the teachers
Individual interview
Rose’s identification with physics was, in part, dependent on how enjoyable the
teacher made the subject or not. Rose recognised that a previous teacher had not
helped her to enjoy physics and so she did not have a strong identification with
it. This second teacher had got her interested in physics because she felt that he
made the physics lessons interesting, fim and relevant; as reported by Osborne
and Collins (2001). She also described how the physics teacher cared about his
pupils and how he would go out o f his way to help them to achieve what they
wanted. He had helped Rose by offering her extra tuition in lunch time and after
school. Rose’s relationships with her two different physics teachers demonstrates
how important a factor a teacher can be on whether pupils will develop a strong
identification with physics and be willing to embrace the figured world o f
physics or not. The relationship between students’ attitudes to science and their
interpersonal relationships with their teachers was reported on by Wubbels and
203
Brekelmans (1997) who found that when teachers acted in an understanding way
to their students, classes were more effective overall. The model used by
Wubbels and Brekelmans (1997) was also used by Fisher and Rickards (1998).
They found that students had a better relationship with mathematics when their
teachers demonstrated helpful and friendly behaviour. They felt that these
interpersonal behaviours between the teacher and the students could be as
important as teaching methods and styles in describing an effective mathematics
teacher.
The importance o f these interpersonal behaviours is clearly demonstrated here in
Rose’s relationships with her teachers and the subject. The first teacher did not
encourage Rose to see physics as an interesting subject that she would be happy
to engage with further. The second teacher changed Rose’s opinion completely
and made her think that physics was a figured world that she would like to
engage with. However, this engagement was teacher dependent; an issue with
students progressing to further study. As Rose described, one o f the reasons she
had not chosen physics for A-level was because she may not like the teacher who
taught her. Rose’s entry into the figured world o f physics and her continued
habitation there was dependent on the teacher. A poor teacher would have meant
that Rose did not feel she could stay in that figured world so rather than risk this
she left the figured world after GCSE.
In her questionnaire Rose said that she felt she was about the same ability in
physics as the rest o f her class and liked physics more than her friends. (These
were the questions used to give a simple measure o f the level o f self efficacy
reported by the students.) In the third group interviews I asked the girls again
about how they would grade their ability in physics relative to their class with
one being the top grade. Rose graded herself at a two.
two ‘cos I’m not top some of my class are definitely like one, they
know everything there is to know about physics
Group interview three
204
When I asked Rose the same question in the individual interview which was after
she had received her GCSE results (she got a A* for GCSE Physics) she admitted
that she would just about score herself as a one but was still not completely sure
o f this.
I guess but I don’t know if it was that I’m good at physics or just ‘cos I
worked really hard and learnt everything so much
Individual interview
Rose’s reluctance to give herself a grade one demonstrates how difficult it is to
measure self efficacy and how problematic measuring just self efficacy alone is
to using it as a predictor of further study (Britner and Pajares, 2006). Using
Bandura’s (1982) four causal factors that affect levels o f self efficacy (mastery,
vicarious, social and physiological) and the proposal by Britner and Pajares
(2006) that o f these four factors the mastery factor has the greatest influence on
self efficacy, we would predict that Rose, who gained a top grade for GCSE
physics, would have a high self efficacy. However, Rose is not confident to give
herself this high level o f self efficacy.
She explained why she was still not sure about giving herself a grade one by
saying:
I think that with everything you have there are things that you just find
easier ‘cos I think I find chemistry and biology easier than I found
physics, just because I think that there are certain, there are just certain
things that come more naturally to you and I think that I find that biology
and chemistry come more naturally to me than physics, but obviously I
do think it was the hard work ‘cos I put lots o f hours o f my time into
learning physics
Individual interview
Even though she expressed the belief that some subjects are naturally easier than
others she was convinced o f the argument that hard work could overcome that
barrier.
205
if you work hard you can, well especially I think, maybe specific at
GCSE level, but I think that if you work hard at GCSE level then
everybody could get an A star at GCSE if you put the effort in
Individual interview
Rose’s relationship with physics is an interesting one. Her GCSE grade o f A*
demonstrates that she can achieve but she is not confident to say that she is good
at physics or has a high physics self efficacy, and puts her top grade down to
hard work. Rose’s belief in hard work meant that she did manage to achieve the
highest grade possible at GCSE. However, she was not sure that she would be
able to achieve the grades needed to achieve well at A-level because it had been
so much hard work to get to the GCSE grade, an example o f how many factors
(mastery o f the subject, perceptions o f hardness, the discourse o f achievement)
can contribute to how we perceive our capability o f learning at a designated
level, our self efficacy and ultimately our subject identity.
Rose is developing an identity that has a focus on achieving her goals and those
goals are focused on her future career and security. She has moved towards a
definite career aim, medicine, from a starting point o f ‘just a job in science’. She
feels that she knows where she is going and that others see her as a person who is
focused on that aim. She has chosen subjects for A-level that she feels are the
best ones to allow her to achieve that aim.
Her identification with physics was very dependent on her teachers. One o f her
teachers encouraged her to embrace the figured world o f physics. Her
achievement o f an A* for GCSE physics could lead to her seeing herself as a
physics person and part o f the figured world o f physics, but her description o f
how she achieved that grade, by hard work only, means that she does not do this.
206
Indiana
Indiana was in year 10 at the start o f the interview process. I met her three times
over the coming four terms . Indiana described herself as White. Her mother had
been a teacher but had had to leave due to illness and now worked in a clerical
job. Her father was unemployed when she completed her questionnaire; he had
previously had a well paid job but Indiana did not say what this was. Her older
brother, who was 25 at the start o f the interviews, still lived at home because he
could not find a job after leaving university whereas her older sister had a job
that ‘had a reasonable salary for her age’.
On her questionnaire Indiana said she was not thinking o f choosing physics
because ‘I don’t find it particularly interesting and I don’t want to have a job
involving physics’. However, the other subjects she was thinking o f choosing for
A-level were product design, mathematics, chemistry and history. She wanted to
study product design and mathematics because she wanted to have a job
involving them whereas history was because o f interest and chemistry because it
looked good. I was interested to find out why she had rejected physics because if
she was so interested in a career that involved product design and mathematics I
could not see how she could avoid elements o f physics in this future career.
This interest in product design was very evident throughout our discussions. This
was the one subject that she was consistent in saying she was going to study for
A-level and was interested in pursuing a career in this area. She acknowledged
that many people thought she was odd for having an interest in the subject,
especially as many saw it as a boy’s subject. Indiana acknowledged that there
were many more boys in her class than girls, but she did not mind this; she
enjoyed the subject and was going to carry on studying it. The figured world of
product design, as described here by Indiana, has many similarities with that of
physics. Both are perceived as being dominated by males. Both are places where
society’s image o f that world is one where girls should not play a part. However,
Indiana feels that she can be a part o f the product design world because she
32 It is Indiana who I did not interview on a one to one basis.
207
enjoys the subject - a parallel for those girls who are interested in physics and
feel that they can be a part o f that world. I could also speculate that, since Indiana
is happy to be part o f one world where she is having to overcome barriers to her
participation (Aikenhead, 1996), she would also be willing to participate in
another, that o f physics, if she wanted to.
Indiana’s participation in the figured world o f physics was not suggested by the
rest o f her questionnaire responses. The rest o f her questionnaire responses were
consistent with a dislike o f physics. Her physics words were ‘bored’ and
‘difficult’. She did not agree with any o f the statements about physics lessons.
She was neutral about her ability in physics and her liking o f the subject when
compared to others, and finally she did not describe herself as a physics type o f
person because it did not interest her.
In the first o f the group interviews Indiana confirmed her dislike o f physics. She
felt that she was good at mathematics (in fact she had already passed her GCSE
obtaining an A grade and was now studying additional mathematics) but that
this did not relate to her being good at physics, even though her father thought it
should.
Mine’s more to do with me being good at mathematics. My dad kind o f
expects me to be good at physics and I don’t really believe that, it is just a
bit o f an effort and then it kind o f bores me as well, causes me trauma.
Group interview one
Indiana’s relationship with physics and how that was influenced by her teacher
came out in the second group interview when I asked the group to tell me about
their physics teachers. In the first interview Indiana had been an active
contributor, willing to discuss her reasons for not liking physics and discussing
who had influenced her future subject choices. Now, asking about her physics
teacher, she talked with real passion about how she felt about him
208
I don’t like him
I’m going to ask why a lot now33
well what was I going to say, um, I really like product
design so I was going to do product design, further
mathematics and physics for A-level ‘cos I want to go into
engineering. I don’t really like physics but it helps you get
into engineering. Otherwise, but like when I said to my
teacher would I be alright doing physics A-level, I’m on a
A, and he just said no, have you ever wondered why you
are in set 3, you are going to get a D if you do it for A-
level, so it was like no confidence in me.
Group interview two
Looking at the words on paper does not bring across how Indiana felt at this
time. Her tone o f voice and her body language clearly indicated how much she
had been affected by this incident. It was obvious that she felt let down by her
teacher, was incensed that he felt that she was not capable o f achieving a good
grade at A-level even though she was predicted a grade A for GCSE and was
confused as to how he came to this conclusion.
At this stage o f the interview I wanted to find out more about this physics
teacher. For several minutes, the interview became focused on this physics
teacher with Indiana leading the discussion. Ruby, also a member o f this group,
was taught by the same physics teacher but in a different group. She agreed with
many o f the comments Indiana made about her relationship with the teacher
since they reflected her own. The third member o f this group, Skye, who had a
different teacher, showed by her body language that she was interested in this
conversation and felt that it was important for Indiana to talk about her
relationship with physics and her teacher in this safe space.
Deborah so you are predicted to get a grade A
Indiana I’m predicted to get an A star but I’m on a A
33 The asking of the ‘why’ question was seen as my role in the interviews and the girls joked about this.
Indiana
Deborah
Indiana
209
Deborah
Indiana
Deborah
Deborah right for physics
Indiana yeah
Deborah so what was his reason? It’s not going to go any further
than this
Indiana that everyone that gets an A ends up getting a D for A-
level which I didn’t really understand ‘cos surely I
don’t think he wants any o f our class to do it ‘cos he
like I don’t know anyone who does like him
can I ask a very leading question34
yeah
‘cos obviously the whole topic is about girls and physics,
does he, are his favourites boys or has he got any girls he
likes
Indiana oh he doesn’t like any o f the boys in our class......... I don’t
know, he doesn’t really have favourites, he just doesn’t
tend to like our class
Deborah I was wondering whether him, you know, if he just
discouraged everybody or it was just girls
Indiana yeah, the highest person in our class also said that she
wanted to do physics and he said don’t do it to her
although she is on A stars in all her sciences he just
seems to think because we are in set three we will be
incapable o f doing A-level but then he is like, it is very
mathematics based so I don’t think you can handle it, but
I’ve done my mathematics GCSE because I am doing
further mathematics and stuff so it’s not really
Group interview two
Indiana obviously felt that this teacher was not supporting her in her possible
future subject choices, but was also not supportive o f other members o f her
group. She felt that he had little respect for her ability, in physics or mathematics,
34 Flagging up that this was a leading question was, on reflection, not good research practice but I felt at the time that this was OK based on the fact that all the girls knew the subject area o f my research.
210
and that he also showed little respect for any members o f her group. Teacher and
student interpersonal relationships are very important in the classroom (Osborne
and Collins, 2001; Wubbels ad Brekelmans, 1997). Even though I asked
specifically if she felt this was due to gender issue directly, Indiana described
how the teacher did not encourage any members o f her group to think about
continuing to study physics. The teacher demonstrated that he did not think that
any members o f this particular class were capable o f achieving a good grade in
A-level physics. Even though members o f this group, including Indiana, were
predicted high grades at GCSE, because they were setted into a lower ability
group, the teacher did not feel they would, as a whole, have the ability to be
successful in physics. This could be hiding a gender issue as most schools have
more girls than boys in their lower ability sets for mathematics and science.
However, this would need further investigation and any direct gender issue for
this teacher cannot be concluded from this short discussion.
That this teacher did not feel that any o f this class was capable o f continuing to
study physics was also reflected in a further discussion when Indiana felt that he
(the teacher) had denied her and the rest o f her class access to an outside talk
about physics because o f their perceived ability.
And there was like a physics talk which literally the whole year went to,
but our class because he didn’t, he said that our class would not be good
enough to do it for A-level
Group interview two
At the third group interview, carried out about four months after the second
interview, Indiana was still talking about how she felt her physics teacher had
actively discouraged her from taking physics A-level.
All o f our year went to a physics talk at one point during the lesson and
we didn’t, we weren’t allowed to go our class ‘cos we weren’t going to be
clever enough to cope with A-level, so it was just like I turned up to
mathematics, ‘cos I am fast track mathematics, and I was like the only
211
one there ‘cos I am the only one in my science group, so I was in
mathematics alone for a whole hour
Group interview three
To still have such a raw feeling about this, a considerable amount o f time after
the incident, shows just how much Indiana had been affected by her teacher’s
attitude.
Her relationship to physics was very influenced by the teacher. She graded her
ability (a measure o f her physics self efficacy) as a three or a four (out o f ten
with one being the highest grade) based on her results, but when asked to
compare herself to others
in our class, we are expected to be done down by the teacher, so worse
Group interview three
Self efficacy can be affected by four causal factors (Bandura, 1982). These
include mastery experience related to previous performance o f tasks and social
persuasion or exposure to judgements about previous experience, generally given
in education as feedback. A higher self efficacy is related to having good mastery
o f the task given and positive feedback. Each o f these causal factors will
influence self efficacy levels to a different extent and individuals will be affected
by them differently. Indiana demonstrated a good mastery o f physics, as
evidenced by her results, so would be predicted to report a high self efficacy, but
this level was reduced by the feedback she received from her teacher, not just
about her results but about her physics experience in general.
Later in the interview when we were talking about whether the girls felt that
physics was a male subject Indiana again talked about how her teacher
discouraged people from choosing physics A-level.
our teacher said to a girl in our class that she shouldn’t do it ‘cos she is
getting good grades, but that she shouldn’t do it at school ‘cos, and that
212
was like makes sense out o f it so she really wanted to do it and
then he was like oh no, that is a boys’ subject and.......
Group interview three
Earlier in Indiana’s narrative I described how her teacher did not encourage any
o f her group to think about continuing to study physics because he felt that they
all did not have the ability necessary for this. This comment above, which is very
surprising to hear in a 21st century classroom, moves this discussion from one o f
general ability o f the class to identifying physics as a boys subject. Whether this
is what was actually said or is just Indiana’s interpretation in light o f the fact that
I am asking her about ‘girls and physics’ is difficult to decide. One hopes that it
is the latter not the former.
At the start o f the research process, Indiana describes her relationship with
physics in negative terms. She does not enjoy the subject, she does not find it
interesting, she finds it to be boring and difficult and is definitely not thinking o f
continuing her study o f it past GCSE. She does however have a very big interest
in product design and mathematics and these are subjects she wants to carry on in
the future and have a career involving them. At some point (possibly following a
careers interview or a discussion about her A-level choices, but this is not made
clear), she realises that to support her future career in product design, studying
physics at A-level will be very helpful. At this stage she goes to talk to her
physics teacher, the person she sees as being a member o f the figured world o f
physics, a person who can help her to move into this world.
This teacher shuts the door on her possible entry into the figured world o f
physics. He tells her that she should not enter this world, that she would not be
successful in that world and that the world o f physics is not for her. His reasons
for this do not make sense to Indiana. He tells her that she will not be successful
at gaining a good grade for A-level because she is in set 3; she would only
possibly gain a D grade. (The school split their students into two populations, an
upper and a lower, based on attainment and even though Indiana is in set 3 she is
in the top population so is taking GCSEs in the three separate sciences). Indiana
is confused by this statement as she is predicated to gain a grade A for GCSE
213
physics (which she did in fact do). Another reason the teacher gives is that she
would not be able to cope with the mathematics side of the physics syllabus.• ^Agam, Indiana is confused by this as she has already achieved a grade A in her
GCSE mathematics, a year early.
It is not obvious to her why this teacher feels that students who gain a grade A
for GCSE physics will only go on to gain a D grade at A-level. This reasoning is
very confusing for Indiana. Gaining a grade A for GCSE indicates a high level o f
attainment and most pupils would expect that this indicates that they have a good
understanding o f the subject and that if they choose to study that subject further
then they will be successful. Not only is this teacher saying that this will not
happen for physics, the statement is causing Indiana to doubt whether she will be
successful in any subject where she gains this grade at GCSE. This is not only
making her identification with physics more difficult but is having an influence
on her overall identity development as a high attaining student.
The teacher also made a statement (by implication through his actions) to the
whole o f Indiana’s class about their lack o f ability by not allowing them to attend
a talk aimed at pupils who could go on to study physics at A-level. This again
demonstrates that the teacher has a major influence on whether any o f his pupils
could embrace the figured world o f school physics.
Charlotte
Charlotte was part o f the Hinton School year 10 Yes mixed group. She was
thinking o f choosing A-level physics because ‘I am good at physics and
understand it as I am also good at mathematics but it is not necessarily my
favourite subject’. Charlotte was one o f the few girls who rated herself as one o f
the best at physics when compared to the rest o f her class although she felt she
only liked physics as much as her friends. This could be because she described a
physics type o f person as someone who was ‘quite geeky’ and she was not sure if
she fell into this category or not, even though she was good at physics. In the
214
end, Charlotte gained a grade A for GCSE Physics which she said was due to her
lack o f effort because she felt that if she had done more work she would have
gained the top grade.
Charlotte came from what could be described as an upper middle class or
professional background. She categorised her father as professional and her
mother as clerical on the questionnaire. During the course o f the interviews she
mentioned a brother who wanted to go into engineering. She felt that her parents
would support her to do what she wanted. She talked about them wanting her to
go to university but that she could choose what subject she wanted to do.
Charlotte’s other original choices for A-level were French and Spanish because
she was good at languages, mathematics because she understood it and
geography because she found it interesting. In the end she chose mathematics,
geology, French and Spanish. She did not choose physics ‘not because I don’t
like physics, that’s just because I preferred other subjects35’.
Charlotte explained that the subjects she finally choose for A-level were
what I am interested in the most, I have absolutely no idea what I want to
do later on, like clueless and it was basically, it was subjects that I did,
partly I did the best at, the ones I enjoy the most and I was most
interested in so
Individual interview
She explained that she did not feel pressurised into choosing particular subjects;
she just chose the ones that were her favourites. She talked about her choices by
saying
I know a lot o f people have said that, that’s like, that’s a random choice
and that is very me, I am very random, so yeah I know in that respect it
35 Geology is only offered by a few schools for A-level.
215
probably reflects myself, but I know, yeah I am, I will go with what I am
confident with and if I am yeah, I am good at this subject I will take it,
see how it goes
Individual interview
Previous research into choices (Eccles et al., 1983; Boe et al., 2011; Pike and
Dunne, 2011) has shown how many post-16 choices are based on future career
goals. It is refreshing to see that not all girls make their post-16 choices with this
focus in mind.
In an earlier group interview Charlotte described herself as
I guess strong, like physically and mentally and I try, yeah positive as
well, definitely positive sometimes
Group interview three
When talking about her subject choices she described how other people might
perceive her choices.
if they think, oh that is a bit weird, why would you do that subject, I am
just like oh, like a lot o f people have said why are you doing geology, it’s
rocks, but I am a climber, I like rocks, rocks is my thing, rocks isn’t your
thing, deal with it, who cares
Individual interview
Charlotte went on to say
I don’t see why we should conform to society’s stereotypical stuff, I don’t
think, I, who cares if you are a guy or a girl just ‘cos you do, like some
people think physics is manly or for men or whatever or is not very girly,
who cares, if you like physics go with physics, it doesn’t make a
difference
Individual interview
216
Charlotte described herself as liking to break stereotypes and described how as a
rock climber she was the only girl o f her standard in her county and so was used
to being the odd one out. Charlotte spoke a lot about climbing, it was her main
hobby. She clearly related her strong physical and mental attitude to her ability in
climbing and her one-mindedness in pursuing a hobby which not many other
girls participated in. She often used the phrase ‘man up’ when talking about how
she felt other girls were not confident to stand out from the crowd and she felt
that this came from her climbing experiences. These references to climbing and
the fact that Charlotte used climbing terms to explain how she felt about how
others saw her demonstrate aspects o f both hetereoglossia (Francis,2010) and
female masculinity (Mendick. 2003 and 2006). To be a climber Charlotte has to
perform many aspects of, what others might term, masculinity; she has to be
strong, active and objective in order to be the excellent climber that she is. This
does not make her, to my mind, ‘more masculine’ than other girls, it just
demonstrates that a binary ordering o f feminine and masculine traits does not
reflect what is actually happening in identity work. Charlotte is happy to perform
masculinity and it does not make her any less feminine, from her point o f view.
She also feels that other girls should have the confidence to perform masculinity,
hence the use o f the term ‘man up’.
She then described how she felt other people might not be as confident as her to
pursue subjects that they felt others would ridicule them about.
I think a lot o f people would think, would worry about what people
thought o f them, should say if I took physics, if yes another girl took
physics and then people said why are you taking physics you should be
taking like history or something like this, which people maybe possibly
see as a bit more, not girly, but a bit more, it is just not as sort of
stereotypical male orientated subject you know, and then yeah some
people, just they go, oh no I am not really sure some people are saying I
should not do physics, I am a girl, whatever, but and I know that would
affect some people’s choices, I know it definitely does, some people
would not take a subject because they think, because o f what they think
217
other people would think o f them and I don’t think that is really right and
that you should just do what you want
Individual interveiw
Charlotte was however confident that things would change in the future and that
more people would choose subjects that they wanted to and would not be so
affected by what others thought. She used girls and physics as an example o f
this.
I think it will change, I think everything changes all the time, so I think it
has to change at some point, but whether that is in the next 10 years or the
next 100 years or whatever, but I guess, ‘cos a lot o f scientists seem to be
men, the sort of founding, like fundamentals o f like physics, a lot o f
brainy people like Einstein and Newton, they are all men, so I guess our
foundation o f physics would be if discovered by men it should be
continued by men, but that is not true, there are female astronauts it
is just time to change, people change and they go actually, maybe this is
more normal or what they perceive as normal, it is changed so much
Individual interveiw
During the course o f our meetings, Charlotte always struck me as someone who
was very comfortable with her own individual identity. She was not afraid to say
what she thought and not afraid to talk about her, what she termed, unusual
hobby o f rock climbing. She also knew that she was very good at climbing, at a
standard above all the other girls in her county, and that this also made her stand
out even in the rock climbing world.
When discussing how she would describe herself, Charlotte demonstrated that
she felt that she knew who she was and how other people saw her. She described
herself as not being affected by what other people thought o f her. However, she
did recognise that other people were so affected and that this could make
identification work difficult, especially if how you saw yourself was different
from how you felt other people saw you. This conflict could result in an identity
more geared towards others than being true to your own ‘inner self. Charlotte
218
did not feel that she had this conflict and that her identity as seen by others was
the same as how she saw herself.
In Rose’s story, we saw how the draw o f a future career had shaped her subject
choices and also her identification with physics. For Charlotte, there is no future
career in the picture. She explains that she has chosen her A-level subjects purely
on interest and enjoyment. She has no idea about what she wants to do in the
future. This is a bold statement. Charlotte feels comfortable with the idea that at
the moment her choice o f subjects to study does not need to be linked to a future
career. She realises that this will come in the future, but for now she is sure
enough o f her own identity to not feel that she has to do what others think she
should do, but that she can do what she wants to do.
Scout
When I first met Scout she was in year 9 at Hinton School. She was very
noticeable in the group; she was the one with the ‘sticky up’ hair that had a
coloured streak in it. The colour o f the streak changed over time and the length o f
the hair did but it remained ‘sticky up’. On her questionnaire Scout indicated that
she did not live in the town where Hinton School is situated but in another small
town about ten miles away. This would mean that she had a longish bus journey
every day and that Hinton School was not the nearest to where she lived.
Studying at Hinton School had therefore been a choice rather than just going to
the local school.
On her questionnaire Scout reported that her mother was from a professional
background and that she did not know what her father did. During the interviews
it became apparent that she lived in a single parent household. She did not
mention other family and when she spoke about home it was just about her and
her ‘mum’. She explained that her mother was a supply teacher and that it was
sometimes difficult because she did not have a full time job. She felt that her
219
mother wanted her to be successful at school so that she could get a good, secure
job in the future.
I chose Scout as part o f the year 9 No to physics but Yes to other sciences group
as she indicated on her questionnaire that she was thinking o f taking biology,
French, mathematics and art for her A-levels. The decision not to choose physics
is often linked to its closeness to mathematics but here was a pupil who was
interested in studying mathematics so this could not be the barrier for her to the
study of physics.
On her questionnaire Scout said that she was not going to choose physics
because she found it hard. Her choice o f words to describe physics in a later part
o f the questionnaire was mixed. They were - ‘like’, ‘anxious’, ‘difficult’,
‘interesting’ and ‘confusing’. My feeling is that Scout was not sure where to
position herself with regards to physics. Some o f it she liked and found
interesting. Other parts o f it confused her and made her anxious. She also thought
physics was difficult.
One theme that emerged in the first group interview and that Scout then
mentioned in all the subsequent interviews was that she did not feel confident
about her ability in physics. One o f the reasons she gave for this was the lack o f
feedback that she received from her teachers.
with marking, it’s like you don’t really know what you are trying to show
when you are doing specific work you don’t really know what you are
actually trying to show, like skills in physics
Group interview one
She linked this lack o f knowing what she was trying to demonstrate in her work
in physics to the lack o f reassurance from her teachers that she was doing the
right thing.
I don’t really, it’s not that you are wrong or you don’t know what to do,
it’s just that I want reassurance that I am doing it right then if you
220
don’t think you are [doing it right] or you think you might have a
different sort o f thing, then they (teachers) can just come over and check
to make sure that you are doing it right, cos otherwise you are going to
feel then, if you haven’t had that reassurance
Group interview two
In the follow up one to one interview I asked Scout again about the relationship
between the feedback she received and her relationship with subjects. She again
agreed that this was an important issue for her.
I kind o f need to know what I have done right and what I have done
wrong in order to feel that I have done well and that I can improve, ‘cos if
I am not getting told what I can improve on then I don’t really get which
bit I have done right
Individual interview
For Scout, when she receives effective feedback this supports her future
performance and allows her self efficacy to increase. It is when she does not get
this type o f feedback that her self efficacy decreases.
The second group interviews focused on teachers and teaching o f both physics
and the interviewees’ favourite subject. Scout linked her liking o f history to the
help she received from the teacher.
if you need help with different types o f exam questions, then she shows
us how to get them on the school website you get lots o f help
Group interview two
Scout contrasted this to her physics classroom where she did not feel that she
could ask for help.
it puts people o f f ‘cos they, oh I can’t put my hand up and say I don’t get
it, ‘cos they always snap at you, don’t get any help
Group interview two
221
As stated above the interpersonal relationship between teachers and their students
has been previously identified by Fisher and Rickards (1998) as being very
important in how students engage with a subject. Scout is more confident in her
relationship with the subject and likes it more when she sees the teacher as being
helpful and approachable. With physics, where she considers the teacher to be
unapproachable, as demonstrated by the statement that the teacher ‘snaps’ when
questions are asked, Scout links this inapproachability with a dislike o f the
subject.
In the third group interview she again spoke about her lack o f confidence and this
time discussed it when asked where she would go for help if she had a problem
in physics. I asked her if she would ask her teacher for help.
Maybe, it is just ‘cos it is top set, you don’t really want to ask the teacher
what it is, ‘cos it feels like everyone else knows what it is, so I would
rather just ask more people on my table rather than ask the teacher
Group interview three
This was expanded on in the individual interview.
there are a lot o f bright people in the top set, are really sure.. ..they know
everything and then if you don’t get something, a lot o f well, quite a few
people, will be like, why don’t you get it ‘cos it’s really easy....so kind o f
if you don’t get it then you kind o f don’t want to tell anyone else that you
don’t get it it kind o f makes you feel you are like not as smart as
everyone else kind o f makes you a little lower on the ability scale
Individual interview
For Scout, the top set is a place o f competition not collaboration. This place o f
competition does not allow self efficacy to increase (Schunk and Meece, 2005).
The top set is made up o f people who perform ‘being smart’. Scout feels that if
you do not perform ‘being smart’ you are marked out as being different to the
other members o f the group. However, Scout did describe herself as ‘being
smart’ in other parts o f the interviews. This appears to me to be another example
222
o f Scout not really knowing how to perform ‘being herself, not the self that she
thinks others want to see or hear about.
Scout also does not think she can compare herself to her peers in her class, so
does not gain in self efficacy from seeing similar others being successful; the
opposite in fact. This perceived lowering o f her physics self efficacy, which
forms part o f her physics identity, leads to Scout having mixed feeling about her
place in the figured worlds o f physics and science.
As mentioned above Scout’s list o f physics words in the questionnaire showed a
mixture o f attitudes to the subject. They were - Tike’, ‘anxious’, ‘difficult’,
‘interesting’ and ‘confusing’. Scout talked about her place in mathematics and
sciences in the third group interview.
Scout
Deborah
Scout
Deborah
Scout
Deborah
I have always felt kind o f like odd though, ‘cos like
mathematics and science, I don’t, that is kind o f like why,
I have think that boys are seen as better at it ‘cos I have
always felt kind o f odd kind o f being the girl who is good
at mathematics and science and things, and I kind o f don’t
have any, well kind of, I am the smartest person in my
family and I don’t have any like close, or my dad or
anything, so it is kind o f like, just kind of odd being a
really smart girl with lots o f smart boys
and that doesn’t make you feel good
well, I don’t mind, it is, is just that kind o f why I see boys
as being more academic ‘cos I have always felt weird, well
being a really smart girl in with boys
do you feel weird ‘cos, that is, do you think other people
I just think other people would think it is weird and like
the groups that I am in is a load o f smart boys and it has
always been, and they are like afraid o f you, really smart
girls, and I don’t think that makes sense or not, that is just
kind o f how I feel
so you would like to merge into the background more or
223
well I don’t mind it, I, just, that is why I see it as that, ‘cos
if you are really smart than, but ‘cos that person who is in
your year who is really smart you just know they are and,
like, you are always expect it to be a boy, ‘cos you are like
a really smart boy who does everything and then, but in
some o f the years in like school, it was just a small one,
and it was like everybody get like, if you are a girl, I don’t
mind, I like being smart but I think that is just why I see it
as boys are better
so the need to change everybody else to it is all to do with
how everybody else sees you and if everybody else
changed
yeah
would you feel better about then
I do think it would make girls like, more to try harder at
getting good science and stuff, because it is not as weird
Group interview three
In this exchange, Scout describes herself as weird and odd for being, what she
described as, smart and for liking the academic subjects o f mathematics and
science. She feels this because she usually finds herself studying these subjects
within male dominated groups, groups she feels she should not be part of. Scout
describes how she feels that most people expect the smartest students in a year to
be boys not girls. As a girl, who is often at the top o f her year group attainment
wise, she feels that she is ‘the odd one’. However, she also says that she likes
‘being smart’ even if it is also weird. Perhaps, as Scout says, it is not really her
who is the odd one out, but it is society’s perception o f who is good at science
that is wrong.
When I interviewed Scout on her own, about a term after this last group
interview, I asked her to read the above section and asked her how she now felt
about being good at science and mathematics. Her response was:
Scout
Deborah
Scout
Deborah
Scout
224
I think I’m, I think I kind o f it actually makes you feel really good if you
are a girl and you are really good at science and mathematics ‘cos you
don’t see anybody, I don’t know, a lot of, a lot o f the other people in the
top set are boys and a lot o f the boys go on about how smart they are and
a lot o f the girls don’t, so I think to be, to find you are good at science
and stuff it feels really good, but I think a lot o f people do think that it is
just boys who are good at science and mathematics and things
Individual interview
When she is talking about how she sees herself in relationship to science and
mathematics this is linked closely to how other she feels other people see her.
I think that I seem sort o f weird and different in the way other people
might see me because I am not, I am not that good at music and stuff
that’s not academic, and then a lot o f people say there are a lot more girls
who are doing less academic stuff or less sciency stuff and that doing
sciency stuff is what boys do, ‘cos there are so many boys in our lessons
as in, even the girls that are in the lessons, in like the top set, a lot o f
people think that they are not as smart as the boys, but they are just in
there ‘cos they are like the smartest girls, I don’t know what else to say
Individual interview
it is just that a lot o f boys who are winding you up, being a girl being
really, really smart is that you are like a boy and that is really weird
Individual interview
I kind of, yeah, I had a bit when you feel like, like why do I, I kind o f
stand out anyway, so like on top o f that, with the like being good at
science and everything, I just kind of, yeah, but definitely, a lot o f the
smarter boys see you and what are you doing
Individual interview
225
Scout appears to be performing ‘weirdness’ or to make herself stand out from the
crowd with her looks as a way o f offsetting how people see her because o f her
liking o f science and mathematics. It is a case o f ‘Oh she looks weird so it
doesn’t matter that she likes boys’ subjects’.
I asked Scout if she had any mechanisms for coping with how she felt other
people, especially the boys in her class, saw her. She had two responses, one
linked to how being smart made her feel and one linked to the good feeling that
she got when she was able to help others.
I know I am smarter than them, yeah, it is just like when you get
something right and they don’t, it just gives you inner happiness
Individual interview
I can help other people so I know I feel good about it, whereas they, they
are not good at helping anyone else, ‘cos they are like, they don’t get why
you don’t get it and when they explain it, it is really confusing still
Individual interview
It is interesting that earlier Scout talked about how not performing ‘being smart’
marked you out in the top set where it was expected that all the students were
smart. Here she talks about how she likes ‘being smart’ and how good it makes
her feel when she can outshine other people. Helping others could be seen as a
feminine trait; demonstrating a caring attitude. This could be seen by others as an
aspect o f ‘being smart’ that is acceptable for girls. However, performing ‘being
smart’ in front o f others, especially boys, can be something that can be seen as
demonstrating a masculine trait and boys may feel threatened by a smart girl.
Scout, in her own mind, knows that she is smart, but does not want to perform it
too often otherwise she performs an identity that others do not think should be
part o f a girls’ identity.
Identity is the process of coming to think we know who we are, who others think
we are and for others to think they know who we are. We come to recognise
ourselves as certain types o f people and others come to see us as those types o f
226
people as well. We do identification work throughout our lives, refining who we
think we are as we encounter different situations. This identity work is done
within figured worlds and we continue to encounter different figured worlds
throughout our lives and come to embrace or reject them as we come to
understand ourselves. Scout’s story is one o f identification work very much in
progress. Scout performs weirdness and smartness within an outsider identity.
She does not come from the same town as most o f the students at this school; so
that marks her as an outsider geographically. She performs weirdness through her
appearance; another aspect o f her outsider identity. She believes that she is
smart; something else that she believes marks her out as an outsider. However,
she does not always perform smartness as she feels this marks her out as a threat
especially to boys in her set.
One o f the figured worlds where this identification work is taking place is that o f
science (science overall at this stage rather than the individual figured worlds o f
each science). Scout is trying to find whether she has a place in this figured
world or not. On the one hand she feels that she does because she likes science
and feels that she is good at the subject. On the other hand her conceptions o f the
figured world are that it is predominately inhabited by men demonstrated by the
fact that there are more boys in the top set where she studies science than there
are girls. Scout is trying to find out whether as a woman she has place in the
figured world of science.
Discussion
The narratives outlined above show us how four girls’ identification with physics
developed over one and a half years. Each o f their overall relationships with
physics is different. There are, however, influences (and influencers) and
discourses that impact on their identifications that are similar.
In this discussion section I begin by describing the key features o f each o f the
four narratives. I then move on to use the literature presented in Chapter 2 and
227
Three to discuss similarities and differences in the girls’ identification with
physics , concluding by using the notion o f identity trajectory to describe each
girls’ developing identification with physics. I close by concluding how looking
at physics identity as a whole, and by using narratives as examples, can give us
insight into ‘the problem’ o f girls and physics.
The four narratives
The first o f the four narratives, that o f Rose, describes a girl who becomes
focused on her future career. Her A-level choices are made so that she will be
able to gain entry into university so that she can pursue that career. She makes
choices that she feels will enable her to gain the qualifications needed for entry
into that career, to move into that figured world, with ease. However, move her
away from that ‘safe path’ and you find that she has worries about her identity.
She is conscious o f the opinions other people hold about her; following a definite
career path means that she knows what they think o f her, but if she moves away
from that, she is not so sure. She also describes how her teachers have influenced
her identification with different subjects.
The second narrative, that o f Indiana, looks at how a teacher can be seen as the
gatekeeper for the figured world o f physics. The narrative develops o f a girl who
is not sure about her place in the figured world o f physics and is not sure whether
she should embrace that world or not. She seeks guidance from her physics
teacher, a person she perceives as a fully participating member o f that world.
How he interacts with her has a major effect on her identification with physics
and her place in the figured world o f physics.
The third narrative, Charlotte’s, is about a girl who feels ‘confident in her own
skin’. She sees herself as being different but is not bothered about what other
people think. She makes her choices based on what she in interested in. She is
not driven by a future career or by conforming to what others think she should
do. She is interested in physics, she feels she is part o f the figured world of
228
physics, but has ultimately decided not to choose it as one o f her A-levels
because there are other subjects she is more interested in.
The final narrative, Scout’s, is one of contradiction and confusion. In some parts
of the narrative, the girl feels happy to be part o f the figured world o f science and
wants to embrace it further. However, she also feels that she should not pursue
science because it is a masculine world. She feels that people see her as being
different because she is good at science and mathematics; subjects that society
thinks girls should not be good at. Scout appears to be an outsider; she at times
embraces this outsider identity but at others wants to not stand out. These
contradictions make it very difficult for her to develop an identity that she feels
comfortable with.
Using narratives to describe influences on identity development
The literature discussed in Chapter 2 highlighted how the decision whether or not
to choose to study physics post -16 was based on a combination o f different
factors and different influencers. I highlighted how choices are made linked to
future careers, how these choices can be influenced by teachers and teaching,
family and peers and by the stereotypical view that physics is dominated by
White, middle class males. We find these themes echoed here in these narratives.
Choices influenced by future careers played a part in three o f the girls’
narratives. For Rose, future career was most important for her. As she focused in
on medicine, she chose subjects that would help her to achieve this goal. Since
she perceived chemistry and biology as ‘easier’ subjects, and physics as a harder
subject, to allow her to gain the top marks needed to enter university, her
identification with physics decreased. Here, not only was her choice o f subject
governed by her future career aspirations but it was linked to the commonly held
belief that physics is hard.
229
Indiana’s possible move towards physics was due to the fact that physics would
be a useful subject to study alongside mathematics and product design; the utility
value (Eccles et al., 1983) o f physics was important here. Indiana was prepared
to overlook her general dislike for physics if it would help her to achieve her
career goal. Her interaction with her teacher, as described below, only reinforced
her earlier feelings that physics was not for her and even though it had a high
utility value, she rejected it.
Choosing subjects because they will allow fulfilment o f a future career goal was,
however, not the reason Charlotte gave for her eventual choice not to study
physics. Charlotte made it very clear that she did not have a career in mind when
she chose her A-level subjects. She chose those subjects that she was most
interested in; those that she enjoyed and those that she had done best in. So even
though Charlotte did not choose her subjects because o f a future career, she did
choose those that she had done well in and thought that she would be able to do
well in again.
Chapter 3 focused on identity and self efficacy. The summaries o f each o f the
girls’ narratives given above briefly describe how, over the one and a half years
o f this project, they carried out identity work to come to think they knew who
they were, think that others knew who they were and that they thought that others
knew who they were all within the many figured worlds that they encountered on
a day to day basis.
These four girls were all girls who conformed to teachers’ expectations o f what
would make a good physics student; they were academic (Brickhouse, Lowery
and Shultz, 2000), they came from White, middle class backgrounds (Brickhouse
and Potter, 2001) and from families where science talk occurred outside o f the
classroom (Olitsky, 2006). However, three o f them, by the end o f the project, had
already shown that they had not chosen to study physics for A-level and the
fourth, Scout, was not thinking o f doing so either when she did make her A-level
choices.
230
The figured world o f physics that all these girls encountered is within the physics
classroom. The figured worlds within these classrooms are systems o f social
activity that are governed by the norms o f that classroom (Varelas et al., 2011).
These worlds are generated by both the teachers and the students but are found to
often follow ‘expected’ lines. Shanahan and Nieswandt (2010) found that
students, especially those who had encountered science classrooms before, had a
clear view o f what the expected role o f a student was within that classroom. The
figured world o f the physics classroom is reproduced along these lines many
times over. This can be called ‘usual school physics’ (following Boylan, 2010),
where a traditional didactic approach is reproduced (Boaler and Greeno, 2002).
Occasionally a different classroom world is produced, that where a more
discussion based teaching model is used (Boaler and Greeno, 2002). Looking at
the narratives, it can be seen that Rose participated in a different figured world o f
the physics classroom than did the other girls. Rose describes her physics class
as:
we all work together and help each other in class and we are encouraged
to do that so it is so much easier for physics my teacher is kind o f
a bit different from theirs the way he teaches is really engaging
Rose’s relationship with her teacher and his teaching methods was such that she
did not feel confident to continue to learn physics if he was not teaching her. This
was also fiielled by the fact that she had not had a similar relationship with her
previous teacher, one who used more traditional methods in his teaching.
In stark contrast to Rose’s relationship with her teacher is Indiana’s. As
described above, he told her that she would not be successful if she chose to
study physics post 16. Brickhouse, Lowery and Schultz (2000) report that they
found that girls who conform most closely to the teachers’ view o f what a
scientist is are responded to most positively. Teachers are acting as a gatekeeper
to the figured world o f science or physics. The only people they think will be
able to fully embrace this figured world are the people they think will fit into it
most easily and be the same as all those who already inhabit that world. Indiana’s
231
teacher did not think that she would be successful as a physicist based on her
predicted GCSE grade and how that would translate into A-level grades.
Whilst physics is being learnt at school, teachers are responsible for giving
feedback to students about their progress and their understating o f the subject.
Feedback is one o f the factors that has been identified (Bandura, 1982) as
affecting the level o f self efficacy. I have proposed that self efficacy is an
integral part o f identity (see Chapter 3, page48). Of the narratives described
above, it was Scout’s identification with physics that was most influenced by her
self efficacy and that self efficacy was most affected by the amount and type o f
feedback she received from her teachers.
Wenger (1999) describes how identities are not static but are developed along a
trajectory. Calabrese Barton et al. (2013) found that along those trajectories there
are moments o f shift when the direction o f trajectory changes due to the person
seeing themselves in a different way or perceiving that others view them in a
different way. Overall, these trajectories can lead to an inbound motion
(increasing identification with), an outbound motion (decreasing identification
with) or a peripheral motion (no movement) (Jackson and Seiler, 2013).
For each o f the girls whose narratives are told above, their developing physics
identities can be described using the notion o f trajectory. Rose and Charlotte
started from a position o f thinking they would choose to study physics post 16
but in the end did not; an overall outbound trajectory. For Charlotte, her
identification with physics did not become outbound until she actually started to
study for her A-levels and then she only did not choose physics because ‘that’s
just because I preferred other subjects’. Up until then, she had had a fairly stable
relationship with physics and she did not identify any particular moments when
her identification had changed. For Rose, her outbound trajectory started when
she made a firmer decision about what she wanted to do for a future career. This
career goal changed from being ‘just something with science’ to wanting to study
medicine. Alongside this firming up o f a future career goal, came Rose’s
relationship with her physics teacher and her deciding that she would be more
likely to achieve top grades in chemistry and biology rather than physics. Rose
232
felt that she would only be successful in physics if taught by this teacher and that
there was no guarantee that she would be taught by him for her A-levels.
Indiana’s physics identity trajectory is one that changed dramatically with one
particular incident. At the start o f the research, Indiana was not thinking o f
studying physics post 16. Her interests were with mathematics and product
design. She had an outbound trajectory. At some point, but this was not told to
me, she decided that for her future career aim of working in product design, it
would be a good idea if she studied physics post 16. She was a high attaining
mathematics student, having taken her GCSE a year early and gained an A* and
she was predicted to attain a grade A for physics. At this moment, she had moved
her trajectory towards in inbound one. She spoke to her physics teacher about
taking A-level physics. He told her to reject the idea as she would not be
successful. The trajectory changed again, very much in an outbound direction
and with Indiana having a very negative attitude towards physics.
The final narrative is about Scout. She started with an outbound trajectory for
physics but an inbound one for other sciences. The overall directions o f these did
not change over the time I spoke to her, but they did undergo ‘ups and downs’.
These related to her interactions with her teachers and her peers. At times when
Scout did not receive the feedback and reassurance from her teachers that she
was succeeding in science, there would be a down, outbound, movement. When
she felt her peers were thinking that she was weird for liking science and
mathematics were other moments o f outbound movement. However, at other
times when she felt she was smarter than her peers (in science and mathematics)
an inbound movement occurred. Other movements back up, or in an inbound
direction, were when she felt good that she could be successful at science and
mathematics even though she was a girl; when she did get something right that
others in her class did not and when she could pass on her knowledge.
These narratives show how important it is to look at physics identity as a whole.
We can identity factors that will influence an identification with physics, but
these narratives show how individual the effect o f those influencers can be. For
some people, a sustained direction o f trajectory along a physics identity will be
233
established following a positive, or negative, influence. For others, the trajectory
will fluctuate with many influencers causing both inbound and outbound
movements, often dependent on how much impact a particular influencer has on
the overall identity development o f that person, since physics identity is just part
o f an overall identity
234
Chapter 8 Conclusion
Introduction
The ‘problem’ o f girls in physics has worried researchers, politicians and people
working in physics for a number o f years, at least since the 1970s. Early research
on ‘the problem’ focused on the differential involvement o f girls and boys in
physics and the differential achievement o f boys and girls in physics at 16
(Bennett, 2003). As further research was carried out, it again mainly focused on
defined areas to explain why girls did not choose to study physics (or in most
cases the research was on science in general rather than just physics).
In this study I worked on two research aims. These were:
1. to interrogate the current literature o f identity and self efficacy to develop
definitions o f physics identity and physics self efficacy and then to
develop a theoretical model linking the two
2. to explore what physics identity and physics self efficacy meant for girls
in school years 9-11 and produce narratives to examine how these impact
on future subject choices.
In order to try to answer these questions I carried out an extensive literature
review (described in Chapters 2 and 3) and I chose a mixed methods
methodology using a funnelling approach to participant selection to investigate
the relationship o f physics identity and physics self efficacy for girls in years 9-
11. This funnelling approach started with a questionnaire given to 202 girls in
years 9 and 10 at two schools. From the responses to these questionnaires 43
girls were selected to participate in small group interviews. Finally, narratives
were developed for four girls from their discussions in the small group
interviews, and for three o f them, a further one-one interview.
235
In this chapter, I draw together the outcomes from these three data gathering
methods. For each o f the identified outcomes, I discuss what my research shows
and I look at the implications o f these outcomes and suggest how they can be
used to understand how girls come to make choices around physics and how to
change practices to encourage more girls (and boys) to choose to study physics
post-16. The research outcomes also include the novel methodology I used and
the theoretical frameworks developed to use in this study. The previous research
in this area focused on ‘the problem’ o f girls in physics as one that the girls
themselves had or one that schools and the physics industry perpetuated. The
limitation o f seeing the lack o f girls choosing to pursue physics as ‘a problem’
will be discussed in the section on theoretical frameworks. I also reflect on the
methodology used in the study and possible limitations o f the choices made. I
conclude with suggestions for future study.
Research Outcomes
Outcomes from the questionnaire results, the small group interviews and the
narratives are described below. Where the outcomes confirm previous research
this is noted by citing relevant sources and, where new contributions to the
literature are made, these are discussed in more detail. These new contributions
are:
• teacher - student interactions
• the discourse o f achievement
• similarity and differences between physics choosers and non choosers
• complexity and interrelationships o f figured worlds.
For each o f the identified outcomes, after I have discussed the contributions to
knowledge, I outline recommendations and implications.
236
Making choices
The girls chose subjects to study in the future because they were interested in
them (Boe 2012). The girls were more likely to prefer biological sciences to
physics (Jenkins and Nelson, 2005) and were more likely than boys to say that
they were thinking o f choosing to study humanities subjects post-16 (Ryan,
2001; Pike and Dunne, 2011). Girls chose subjects to study post 16 because they
felt they were needed for future careers (Cleaves, 2005) and this was especially
the case for those who were thinking o f choosing physics (Boe et al., 2011).
Choosing a future career is part o f developing one’s identity. The career choices
made are often one o f the first things that people use to describe themselves (i.e.
I am a teacher, I am a doctor, I am a film maker etc.). From the questionnaire
results, more girls made subject choices based on future careers than did boys. Of
those students who were thinking o f choosing physics, 57% of year 9 girls cited
career as a reason for choosing it compared with 36% of year 9 boys and for year
10 girls it was the reason 44% gave compared with 29% o f year 10 boys. I
suggest that this focus on careers is because girls make decisions about what
career to pursue sooner than boys and so choose subjects with this in mind. There
is not enough data here to definitely conclude that that this is the case, but this
was a trend shown by this data. Further research would be needed to investigate
this factor, and to see whether these career decisions are fixed at this early age
and what information was used to inform these choices.
The girls in this study were predominantly from White, middle class
backgrounds. These families would encourage their children to choose
professional careers. This could be linked to why girls in this study were already
choosing subjects linked to future careers.
Girls thinking of choosing physics reported that they came from scientific
families and so were exposed to scientific language in the family (Olitsky, 2006).
These girls would be aware that choosing a scientific career was suitable for
them because at least one o f their parents also had this type o f career. This trend
237
has also been observed in the ASPIRES project (Archer et al., 2013). These
results could indicate that future scientists will only be recruited from those
families who are already familiar with science and so encourage their children to
pursue a similar career.
Girls who were thinking o f choosing physics post 16 described it as interesting
but also difficult. Linking physics with difficultly is part o f the commonly held
belief that physics is hard, masculine and objective (Francis, 2000). This
stereotypical image o f physics as being hard, masculine and dominated by White,
middle class males was acknowledged by the girls as something that did deter
some from choosing it (Ryan, 2011; Francis 2000). They said that this should not
be the case; that subjects should not be seen as gendered and that girls should not
be seen as any less feminine if they chose to follow careers in what society
perceived as masculine areas. However, all girls did make ‘slips’ (Baker and
Leary, 2003) when talking about this topic, maybe showing how difficult it is to
move away from messages that form an early part o f identity development.
These wider societal influences on choices need to be tackled by schools and
teachers. Raising awareness o f why these should not be used as reasons for
making choices should form part o f careers education in schools.
Teacher - student interactions
The work o f Osborne and Collins (2001) highlighted how much pupil’s interest
in science classes was influenced by their teacher. They reported that pupils in
general said that their interest in science was raised by teachers who made their
lesson ‘fun’ and that girls in particular responded well to teachers who devoted
time to clarification o f content and who built up a good relationship between
themselves and pupils. My findings support these claims, add colour and also
draw attention to one aspect not highlighted in the literature before, that o f the
impact o f non subject specialists.
238
Teacher - student relationships and how they impact on physics identity and
physics choices were discussed by all the girls in the group interviews (see
Chapter 6). The narratives, described in Chapter 7, clearly demonstrated how
teacher - student relationships impacted on individuals. These relationships
could have both positive and negative influences, so teachers need to be folly
aware o f how their actions, both in a classroom and generally with students, can
affect girls’ physics identity work.
The majority o f girls described a physics classroom as following ‘usual school
physics’ (following Boylan 2010). These physics classrooms are being
reproduced throughout schools all over England (if not the world) and many
people would recognise them as such. Rose, in contrast, described her physics
classroom as being much more collaborative and that she felt this had greatly
enhanced her relationship with physics. However, it was the atypicalness o f this
physics classroom that in the end resulted in Rose not choosing to study physics
post 16. Even though this collaborative approach to learning physics resulted in
Rose having an inward trajectory for physics identity at his time, this trajectory,
in her view, could not be sustained if she continued to study physics without this
teacher. Her physics identity was dependent on how the teacher taught physics.
She did not feel that she could sustain her physics identity in a ‘usual school
physics’ setting.
Another aspect o f ‘usual school physics’ that was highlighted by the girls, and in
particular Scout, was that this type o f classroom was often perceived as a
competitive classroom. Scout felt that this was particularly so in the top set. She
did not feel that in this type o f classroom the teacher gave her enough feedback
and reassurance that she was succeeding in science and she did not feel that she
was able to ask for clarification if she was unsure. This resulted in a lowering o f
her self efficacy, a constituent part o f her identity.
The girls in this study described their best teacher, irrespective o f subject, as
those that took an interest in them, both for their subject but also overall. These
teachers not only saw the girls as being part o f the figured world o f the subject
they were teaching but that that figured world formed a part o f the girls’ overall
239
figured world. Indiana, in her narrative, described how her physics teacher
focused solely on the figured world o f physics and how he acted as a gatekeeper
to that world. Since he did not feel that Indiana, and the other members o f her
class, were capable o f hilly participating in the figured world o f physics, he
closed the door to them. Indiana described how this had a significant negative
impact on her physics identity.
Subject knowledge is important and has been highlighted by the Institute o f
Physics (2012) in their work to encourage more physicists to become teachers.
Teachers who are subject specialists can instil a love o f their subject by their own
strongly positive identification with that subject. Contrasting with this I also
found that some o f the girls in year 9 at Browning school reported that they did
not feel as confident to enjoy and take an interest in a science subject when
taught by a teacher who declared that they were teaching outside o f their
specialism. It was not just the teachers’ perceived lack o f subject specialist
knowledge that the girls discussed, but the manner in which they talked about the
subject if it was not their specific area o f specialism. The girls felt that if the
teachers were saying that they were not interested in the subject then they should
not be too. One girl commented that her best science teacher was one who she
did not know which particular area he was a specialist in; he had taught all areas
with the same enthusiasm and knowledge and he had shared this with the class.
The Institute o f Physics has also worked to improve the subject knowledge o f
non specialists with continuing professional development interventions. These
‘solutions’ are to be welcomed, but they only cover half the story, since it was
not just subject knowledge that the girls highlighted here as an issue; it was how
teachers themselves identified or otherwise with the subject and how they
expressed that to their students that was significant. Negative messages from
teachers demonstrated by lack o f enthusiasm and comments such as ‘I’m a
biologist so I don’t know how to do that (in physics)’ were shown not to help to
develop a positive identification with the subject. Further work would be needed
to discover how robust this finding is.
240
This discussion about non specialist teachers highlights the issue as to whether
teachers o f science subjects should be thought o f as science teachers or as
teachers o f biology, chemistry and physics. Related to this discussion is that o f
whether the science subjects should be taught as the separate subjects or as
combined science and at what point in secondary education this differentiation, if
needed, should be made.
Recommendations and implications
The implications o f these findings are not just for the recruitment and training o f
science teachers but also for the management o f the schools involved.
When prospective science teachers are being trained, they need to be made aware
of the impact that their own negativity can have on students and how positive
enthusiasm and interest for all subjects can have an energising and positive
influence. This is part o f their own identity work towards becoming not just a
scientist but a science teacher. This should form part o f their professional
development and be highlighted in their professional portfolio. This highlighting
o f the impact they can have on students should not, however, just focus on their
subject knowledge, but on all aspects o f their interactions with students. They
need to be made aware that the figured world o f the subject they teach is only
one o f the many worlds that interact together in the overall figured world o f that
student and how all these figured worlds interplay in an individual student’s
identity work.
Schools, when recruiting new teachers, need to be aware whether they are
looking for subject specialists or for general science teachers who have a positive
attitude and enthusiasm for all science subjects. This should be assessed during
the interview process. Whether schools are looking to recruit subject specialists
or general science teachers will depend on how the science curriculum is
managed within that school. Schools will need to be clear about whether they
teach the separate sciences using subject specialists or whether they want a more
flexible work force. They will also need to decide when they differentiate
241
between the sciences (both the schools in this study taught the sciences as
separate subjects from year 10). If this is the case, they need to ensure that when
teachers teach outside o f their own stated specialism that they do so with
enthusiasm. This should form part o f the internal appraisal system.
The discourse of achievement
As described in Chapter 2, one o f the stereotypical images o f physics is that it is
hard (Ryan, 2011). The girls did describe physics as hard but this was only part
o f a discourse linked to difficultly and choice. Even girls who were very
successful in GCSE physics did not choose to pursue it. The stereotypical image
o f physics as hard is a discourse that is generally held by society. Maintaining
this discourse allows those who work in the physics industry to hold a certain
status; they have been successful in a hard subject so therefore they must have a
higher level o f intellect than the majority of society. Opening up physics to a
wider range o f people by encouraging more students to study it post 16 would
lower this high status and those already in the industry may feel that their
position in society is diminished.
The girls also described how they felt that they had to achieve the best possible
outcomes in their studies and that they chose to pursue subjects that would allow
them to achieve highly easily. They did not feel that choosing physics would
help them to achieve these goals. I termed this the discourse o f achievement.
The discourse o f achievement is linked to self efficacy; a person’s belief in their
ability to perform tasks at certain levels. Boys demonstrated higher self efficacy
than girls (Brtiner and Pajares, 2006). One factor that can affect the level o f self
efficacy is that o f seeing similar others perform a task. For the girls in this study,
they reported that they did not feel that their self efficacy was enhanced by
seeing similar others’ achievement; in fact they felt the opposite, that their self
efficacy was reduced. This was especially the case when test and examination
results were shared in the class. Hearing what level others had achieved, even if
242
they had achieved highly themselves, did not make them feel that they would be
able to repeat this achievement in the future and in some cases reduced their
belief in their ability.
The discourse o f achievement, that I identified and described in Chapter 6,
however, goes further than just self efficacy. It is also linked to perceived
hardness o f subjects; but again goes further. The discourse o f achievement
combines both o f these but goes further so as to look at all aspects of
achievement and how it is measured. The discourse o f achievement is part o f
modern society’s requirement that everyone should achieve in examinations as
highly as they can and in as many subjects as they can. Society wants students
who are good all rounders; they do not want students who can achieve a high
grade in a ‘hard’ subject like physics but who cannot achieve that same level in
all the other subjects they study. Achieving highly in a ‘hard’ subject takes more
effort and a higher self efficacy than for a subject that is perceived as easy and
one in which it is easier to be more successful. For many girls the need to be
successful outweighed their need to choose subjects that they enjoyed, especially
if the subjects they enjoyed were those that they felt were hard. Girls did not feel
that they were meeting society’s expectations if they concentrated on those
‘hard’ subjects they enjoyed but where they did not feel that they were
‘guaranteed’ to achieve high grades.
Recommendations and implications
In order to overcome the pressures placed on students by this discourse o f
achievement, we need to encourage students to be prepared to take risks. We
need to change the emphasis in education from ‘results mean everything’. We
need to encourage an emphasis on learning for enjoyment and that learning is a
continuous process that does not stop once a subject has been ‘dropped’ from a
student’s study list. The change away from a ‘results mean everything’ discourse
needs to come from government. We need to question as to whether this
discourse is actually leading to an improvement in schools, teaching and results
or whether it is just adding to the pressures on students, teachers and schools to
243
perform in ways that do not actually enhance learning but just meet targets of
performance set by government.
Change is also needed in society. Society needs to acknowledge differences that
mean that not all students can gain a certain level at a given time in the subjects
they study at school. We, parents and teachers, need to encourage all students to
achieve to their best in any subject they choose to study, not a predetermined
level set by external agencies.
Similarity and differences between physics choosers and non
choosers
Analysis o f the data from the questionnaires and from the small group interviews
showed much agreement with previous work. In questions asking about teachers'y/r
and lessons possible choosers o f physics were generally more positive about
their teachers than non choosers. For lessons, the views were fairly neutral with
only one area, practical work, being highlighted as adding enjoyment to the
subject by all groups o f students (Osborne and Collins, 2001). Overall, the data
from the questionnaire generally showed that there was a difference between
possible choosers and non choosers o f physics in the answers they gave to all the
questions, with the possible choosers giving more ‘positive’ responses. The
results from the questionnaire do, o f course, show that not all girls who are
thinking o f choosing physics will always give the same responses, but some
trends can be observed that show differences between possible choosers and non
choosers. When looking at the small group interview data, I expected that these
same trends between possible choosers and non choosers would be observed and
that the interview data would explain why these variations existed. This was not
the case.
In the majority o f themes explored in the interviews, there were no discemable
differences between those girls who had originally expressed that they were
36 Science teachers and lessons in year 9 and physics teachers and lessons in year 10
244
thinking o f choosing physics for A-level and those who had not; between the
different year groups and between the two schools. I would have expected, based
on previous research and my own data from the questionnaires, that girls who
were not thinking o f choosing physics would have given more negative
comments about their relationship with physics and would have been more likely
to hold stereotypical views about physics than those girls who had expressed an
interest in choosing physics in the future. When I actually looked at the quotes
once they had been ordered thematically, it was noticeable that there was in fact
very little difference between the different groupings o f girls. The only area
where differences were marked was that those girls who were thinking o f
choosing physics or other sciences reported having parents with a scientific
background whereas those not thinking o f choosing physics or other sciences did
not (see early section for discussion of this).
These findings are only for this group o f girls who were a subset o f the girls (and
boys) who completed the questionnaire and may not be reproducible for a larger
set o f girls or ones from different socioeconomic backgrounds. The majority o f
girls involved in this research were from a White, middle class background.
However, it does show that care needs to be taken when using just survey data
alone to describe what ‘the problem’ is with girls and physics.
Why then were the differences observed in the questionnaire not repeated in the
interview data? The questionnaire data gives a snap shot o f what the girls thought
at that time. This could have been influenced by recent experiences in science
and physics; by which lesson they were completing the questionnaire in; by
putting the answers expected rather than the ‘real’ ones and by the limits
imposed on the answer categories (e.g. how much can you only agree, disagree
or not with a broad statement about your science teachers, especially if you have
more than one). The interviews gave the girls the opportunity to talk in more
depth about some o f these areas and therefore, possibly, to reach further beyond
stereotypical or expected answers. An example from my own schooling springs
to mind to demonstrate this further. I never enjoyed studying English. However,
my O’level English teacher was very good; she delivered interesting and
stimulating lessons; gave extensive and detailed feedback on the essays I wrote;
245
and I had a very good interpersonal relationship with her. However, this did not
make me any more interested in the subject as a whole, and these lessons,
although interesting, were not ones that I particularly looked forward to. If
completing a questionnaire about English lessons and the subject in general, I
would have given fairly negative responses, but in an interview, I would have
spoken about how much I respected the teacher and how interesting she did make
the lessons. I feel that a similar effect has been observed with the girls I
interviewed about their relationship to physics.
Recommendations and implications
These findings show how complex the reasons are why we choose or don’t
choose to study a subject further and how they cannot be ascertained easily by
using just questionnaires. For teachers and schools who are trying to encourage
more girls to study physics, using questionnaires to find out what they think o f
their physics classes and teachers can form the start o f an intervention
programme. This intervention programme needs to be for all students. This
research has shown that there is actually very little difference between future
choosers and future non choosers o f physics. If only certain girls (i.e. those who
express an interest in choosing physics at a given time) are chosen to participate
in an intervention programme to improve the level o f physics choice, then
teachers will be excluding girls who may in fact go on to chose physics but who
did not show an interest at that time. Teachers are making a choice for their
pupils; they are acting as gate keepers to a subject rather than opening it up to all.
Many girls may not express an interest in physics if they do not know what
careers it can lead to (as described earlier, girls have a career focus from an early
age) and it may be exposure in an intervention programme to the possible careers
physics can lead to that could encourage more girls to study it. Limiting the
exposure to such an intervention programme will also limit the number o f future
physics choosers.
246
The results o f a questionnaire can inform schools and teachers o f what they need
to do in their lessons to improve progression, but they need to do this as part o f a
more extensive programme that looks at all aspects o f choice. Teachers also need
to be encouraged to use their own stories o f how they came to choose subjects to
develop activities for students. Physics teachers sharing their stories can be used
to illustrate the many ways a person can identify with physics.
All o f this needs to be framed by identity development; not only o f an
identification with physics but o f a girl’s (or boy’s) overall identity work that
takes place during their school years. Further research needs to take place
looking at how subject choices and identity development are interlinked and how
these both develop and change over time. A longitudinal approach using
interviews and a narrative interpretation would give much rich data about this.
Reflective interviews looking at life stories and how a person’s choices o f careers
and subject interests changed over the years and the factors that influenced those
changes would also give insight into how choice forms a part o f identification
with physics.
Complexity and interrelationships of figured worlds
The contradictions and variations in how we describe our relationships with a
subject are particularly noticeable when you look at an individual’s reasons for
choosing or not choosing a subject and the factors that influence them. Taking a
more holistic view, and investigating how these influencing factors come
together, led me towards creating narratives to look at individual girls’
relationships with physics. These narratives explore how all these factors, taken
together, impact on choices. Some factors can have a bigger influence than
others. The impact o f different factors can be similar or different depending on
how an identification with physics develops within a person’s overall identity.
These narratives are both ‘typical’ and individual; and they clearly show how
looking for one answer to ‘the problem’ is not practicable.
247
The main place where young people learn physics is in the figured world o f the
physics classroom. This physics classroom was described in a variety o f ways by
the girls in this study. Some o f them described a classroom which was dominated
by competition; some a classroom where only a limited range o f teaching and
learning methods were used as opposed to some where a wide variety o f methods
were used; some where the teacher made sweeping assumptions about his pupils’
ability and interest in physics; and some a classroom where cooperation occurred
between the students and the teacher. The girls’ involvement in these figured
worlds clearly influenced them developing different identifications with physics.
Those where cooperation and a variety o f teaching and learning methods were
used resulted in the most positive identifications with physics and those with
competition, limited teaching and learning methods and a dominating teacher, to
a less positive identification with physics. My study only gives a limited
description o f the figured worlds o f these classrooms and a more in-depth study
o f this figured world, by using extensive lesson observations, would need to be
carried out to further describe the link between the figured worlds o f the physics
classroom and identification with physics.
This classroom figured world sits within and alongside other figured worlds that
make up the student’s day to day world. The individual figured worlds o f the
different school subjects fall within the wider figured world o f the whole school;
which could be described as the school culture. The narratives described in
Chapter 7 are for girls who all studied at the same school. In Chapter 7 I
explained how I had come to choose these girls. As outlined above, in general
there were no observable differences between the responses in the small group
interviews from girls at both my study schools. However, there must be some
differences between the cultures at these schools in order for the girls who I
chose for the narratives to all come from the same school. On the face o f it, the
schools are very similar; they are successful schools with outstanding Ofsted
reports, they serve the communities on the outskirts o f similar towns; and the
pupils are predominantly White and middle class. The differences must therefore
be within the school culture. Researching how the whole school culture can
influence identification with physics and so lead to certain choices would be
interesting but difficult.
248
Recommendations and implications
Choices are considered to be part o f identity work. What we choose to study
forms a big part o f who we are. Therefore, those factors identified in Chapter 2
that influence choice can also be considered to influence identity development.
Factors that influence the level o f self efficacy, reported in Chapter 3, will also
influence identity development if we believe, as I have argued, that self efficacy
is a component o f identity. The overall effect will result in the individual having
a more positive or more negative physics identity, leading to an inbound or
outbound trajectory (Barton et al., 2013; Jackson and Seiler, 2013). The stronger
the identity, the more likely they are to choose to study physics post 16.
The four narratives described in detail in Chapter 7 show four different
trajectories o f physics identity and show how differing factors affect those
trajectories at differing times. They illustrate how coming to understand physics
choices needs to be placed within the context o f an identification with physics.
For those people who can influence choices by influencing identity work, an
understanding o f how their influence works alongside those o f other factors is
important. It would be impossible for those who work with students to produce
an identity trajectory for each student or for each student’s relationship with each
subject they study. What is important is for those people to have an
understanding o f how different influences can affect students’ identity
development and how these impact on choice and that there is a very complex
interrelationship between all the factors.
Researching Girls and Physics
The research outcomes discussed in the section above focus on those outcomes
from the data gathered in the questionnaire, the small group interviews, and
created into narratives. This section focuses on the research outcomes from the
methodological processes developed to research the aims outlined above and the
theoretical framework developed to discuss the findings.
249
This section o f the chapter also includes a discussion o f the limitations o f the
research and suggestions for future directions and further research.
Methodological processes
Physicists (and other scientists) like numbers. Being able to say that X percent o f
girls choose to study physics post 16 because o f Y reason feels comfortable.
Much o f the previous research into ‘the problem’ o f girls and physics has been
done in a quantitative paradigm which makes it more approachable for teachers
who have this scientific background (for example surveys carried out by Stewart,
1998; Spaull et al, 2003 and 2004; Bennett and Hogarth, 2009).
Research focusing on identity development in science and mathematics has been
carried out using qualitative methods. These include individual interviews (for
example Brickhouse, Lowery and Shultz, 2000), group interviews (for example
Pike and Dunne, 2011) and narratives (for example Sfard and Prusak, 2005).
This research gives insight into why girls do and do not choose to study physics
and about how their relationship with science (and physics) develops over time.
The methodological approach used in this project I have described as a mixed
methods methodology with a funnelling approach to participant selection. At the
start o f the project, a questionnaire was given to 458 year 9 and 10 pupils at two
schools who had been identified by their teachers as having the necessary
attainment to be able to progress onto A-level physics if they so chose. This was
followed by semi-structured small group interviews with 40 girls. Following on
from, and using the data collected in these interviews, I selected four girls whose
narratives I wanted to tell. I interviewed three o f these girls further to gather
more data for these narratives.
As outlined above, using qualitative methods to investigate ‘the problem’ o f girls
and physics is less common that using quantitative work. There have been recent
examples o f following up large scale quantitative inquiries with smaller scale
250
qualitative interviews, usually individual interviews (for example the ASPIRES
project (Archer et al., 2010, 2012 and 2013); and the UPMAP project (Mujtaba
and Reiss, 2012a and 2012b)). Using small group interviews as the main data
gathering tool to get a rich, thick description as to how identity influences
choices in physics is rare, if not novel.
My work shows that this approach can be used in this field. Using narratives as a
methodological approach to describe how science identities develop is becoming
more used in research in the US. Using this approach to investigate developing
identifications with physics and how this impacts on choice is again rare,
especially in the UK, and my project contributes to this growing body o f work
exploring the use o f narratives. The narratives described here are not
generalisable, but they are recognisable. They give a picture of how for these
girls their identity with physics impacted on their decision not to study physics
further. Using a narrative approach also allows us to investigate how a
relationship to physics is filtered through all the other relationships that occur
when identity work is taking place. Identity and narrative can potentially give us
a holistic view o f how choices as to whether to study certain subjects or not are
made.
Theoretical frameworks
Blickenstaff (2005) identified nine explanations that had been put forward to
explain ‘the problem’ o f girls and physics and Murphy and Whitelegg
categorised the literature discussing girls and physics and/or science into six
groups.
Table 8-1 Comparing Blickenstaff with Murphy and Whitelegg
Blickenstaff (2005) Murphy and Whitelegg (2006a)
Biological differences between men
and women
Interests, motivation, course choices
and career aspirations
251
Girls’ lack o f academic preparation for
a science career
Relevance and curriculum
interventions
Girls’ poor attitude toward science and
lack o f positive experiences with
science in childhood
Teacher effects
The absence o f female
scientists/engineers as role models
Single-sex schooling and groupings
Science curricula are irrelevant to many
girls
Measures and perceptions o f difficulty
The pedagogy o f science classes
favours male students
Entry and performance patterns in
physics: the impact o f assessment
processes and techniques
A ‘chilly climate’ exists for
girls/women in science classes
Cultural pressure on girls/women to
conform to traditional gender roles
An inherent masculine worldview in
scientific epistemology
In my own review o f current literature in Chapter 2 ,1 categorised it into five
groups which were:
• general attitudes to science and physics
• subject choices linked to future careers
• the influence o f teachers and teaching on subject choice
• the influence o f others on subject choice
• the image o f physics.
These five groupings offer a new framework for discussing the issues that
contribute to ‘the problem’ o f girls and physics.
A more recent trend in science and physics educational research has been to look
at identity. This body of research, although using a variety o f definitions o f
252
identity, has moved the focus away from separately identified causal factors to
looking at how the development o f an identification with science (or physics)
forms part o f a young person’s overall identity. Linking subject choices to
identity forms part o f what Holmegaard et al. (2012) describe as the
Scandinavian tradition o f investigating choices where they see choices as
forming part o f a students’ construction o f an attractive identity. This research
uses the notion o f a developing identification with physics as a basis for a
student’s choice as to whether or not to study physics post 16 or not. However,
research using identity as a basis for explaining future physics choices is limited
and my study has made a contribution to addressing this gap in the literature.
Self efficacy is recognised as a psychological phenomenon and research into
science and physics self efficacy has been focused in the quantitative paradigm
(for example, Brtiner and Pajares, 2006; Haussler and Hoffmann, 2002). Some
recent work by Usher (2009) has used a more qualitative approach to investigate
mathematics self efficacy. As described in Chapter 3, my belief is that self
efficacy is one component o f identity and so the two should be researched
together.
My proposed theoretical framework for using identity to research future physics
choices is based on the description o f identity as a process where we come to
think we know who we are, we think we know who others are, that they think
they know who we are and that we think we know who others think we are. This
work towards our identity is carried out in figured worlds (Holland et al., 1998).
It is in these figured worlds that we come to recognise ourselves and others as
certain types o f people. Our belief in how well we can learn or perform actions;
our self efficacy, is part o f this coming to know ourselves. The choices we make
are part o f us coming to know who we are. Using a framework based on identity
and self efficacy development within the figured world o f physics to investigate
reasons for choices is a novel and powerful way o f researching ‘the problem’ o f
girls and physics.
Throughout this research project I have used the term ‘the problem’ o f girls and
physics. Previous research has focused on ‘the problem’ o f girls in physics as
253
one that the girls themselves had or one that schools and the physics industry
perpetuated. Using the term ‘the problem’ implies that there is a simple answer to
curing it. However, the many reasons proposed for the cause o f ‘the problem’
and interventions used to solve it have not resulted in a solution or more girls
choosing to study physics post 16. This research study has shown that ‘the
problem’ o f girls and physics is a complex one. Using identification with physics
as a lens for investigating choice provides a new contribution to the debate.
There is no quick fix to solving ‘the problem’ o f encouraging more girls (and
more boys) to choose to study physics post 16. Using this more holistic view
should also make us realise that ‘the problem’ is not a good way o f describing
the issue - whose problem is it? Perhaps this is the question that needs to be
answered first.
Limitations of the research
At the start o f this project I proposed to carry out a two school case study. The
methods o f data gathering for this case study would include a questionnaire,
small group interviews, lesson observations, possible informal interviews with
teachers and use o f supporting evidence. This would have meant that data to
answer the research questions would have come from both students and teachers
and my own observations and would have allowed triangulation to take place.
The reluctance o f the teachers at one o f the schools to allow me to observe their
lessons lead to my decision to focus on narratives. Therefore the research is
student centred; the teacher voice is suppressed.
The schools chosen for this study were both situated in areas where the majority
o f their students came from White, middle class backgrounds. This does not
mean that the data is any less meaningful; it just means that it is for a particular
group o f girls. This means the narratives given are typical but not generalisable.
For a more generalisable collection o f narratives, girls from a range o f socio
economic and ethnic backgrounds would need to be interviewed.
254
The questionnaire was given to 458 students in year 9 and 10 at two schools.
This gave me background to the thinking o f the students in these two schools and
two year groups, but when I sub divided the data into year groups and those who
were thinking o f choosing physics and those who were not, some very small
groupings resulted. This meant that valid statistical data could not be reported.
To see whether the trends I did observe in the data from the two schools is
typical a larger sample would need to be used.
Forty three girls were invited to participate in the group interviews. Forty girls
participated in at least one group interview with 31 participating in all three. As
outlined in Chapter 6, even though I had an interview question schedule, I did
not rigidly stick to this and allowed the interviews to develop as discussions
when the girls had plenty to talk about. This meant that not all the questions were
answered by each group o f girls.
During the discussions, even though I ensured that all girls had the opportunity to
contribute to the discussions, they did not always want to. When transcribing the
interviews, it became apparent that in some instances some o f the girls had been
very quiet and only contributed agreements with comments rather than making
their own. When choosing examples o f talk, this meant that comments were not
chosen from all the girls. However, on re-reading through the original transcripts
to check that I had got the overall feel o f the interviews correct and that I had not
missed out any important issues, especially if girls had contradicted what I had
summarised, I believe that I had managed to capture the general feelings o f all
the girls involved, even if I had not quoted from them directly.
This analysis o f the data showed that the group interviews could be used to
illustrate points made on the questionnaire and give a thicker description o f some
of the findings, but that they did not fully capture how girls’ physics identities,
including their physics self efficacies, developed and changed during their
interactions with the figured world o f school physics over the time that I
interviewed them. The interview data, as with the questionnaire data, gave
snapshot views (as illustrated in the methodology chapter (Chapter 4) when I
described how the girls reflected back on the discussions made in the first
255
interview when they reviewed it). As Barton et al. (2013) and Jackson and Seiler
(2013) describe, identities can be thought o f as developing along a trajectory. To
investigate how physics identities developed, I chose five girls (which became
four - see Chapter 4) whose identification with physics had developed over the
course o f the interviews.
The narratives given here are for four girls, three who had already made the
decision not to study physics post 16 and one who indicated that this was what
she was thinking o f doing. To give a more rounded picture o f how identification
with physics can influence the decision to choose physics it would have been
good to have had at least one narrative for a girl who did in the end choose to
study physics.
In all o f this research I, myself, can be a factor that influences the data collection.
Once I started the interviews, I made the girls aware that I was a teacher,
although I had never taught in schools, and that I was interested in the subject o f
girls and physics. This could have influenced the girls to give me the responses
that they thought I wanted to hear. The interviews were a co-construction
between the girls and me. My background as a woman with an interest in gender
equality in the sciences meant that I needed to be aware that I did not allow my
prejudices and preconceived ideas to impact on the questions I asked or the way
in which I asked the questions so as to only get the information I needed to
support my ideas. I needed to be open to all responses, even those which were
the opposite o f mine. When analysing the data, I needed to be aware that I was
telling the story o f the girls, all be it my interpretation o f their stories. I tried hard
to ensure that it was their voice, not mine that was being told. With any study
researchers need to be aware o f their own influence both on the collection and
analysis o f data.
Future directions and further research
256
The work started for this thesis opens up some new avenues for future work. As
outlined in Chapter 2, there is a shortage o f research that has been carried out
investigating girls’ experiences o f science and physics in schools in England and
how these experiences inform future aspirations (and so future choices to study
physics post 16) (Murphy and Whitelegg, 2006a). Research on choices in
English schools has had a focus on understanding how students’ background,
especially their social class, can affect choices. Using identity as a focus for
understanding choices has been the focus o f choice research in Scandinavia
(Holmegaard et al., 2012). Research on physics identity and science identity in
general has mainly been carried out in the US with pupils from poor, urban
backgrounds. Some recent research as part o f the ASPIRES project has looked at
science identity formation in English primary schools. There is therefore still a
large gap in the research literature; both looking at physics identity in general
and how physics identity is linked to choice in English schools.
Narratives have been used to produce a more in depth picture o f how identities
develop over time. The narratives here have been produced by talking to a small
number o f girls over a period o f time. Narratives can also be produced by using
retrospective techniques. It would be valuable to see if narratives from women
already working in the physics industry could be used to confirm that physics
identity and physics self efficacy and the factors that influence them are linked
and that their choice to study physics could be explained in a similar way to the
explanations used in the narratives in this research.
My four narratives focus on girls who did not in the end choose, or propose to
choose, to study physics post 16. Only a very small number o f the girls in my
research actually did choose to study physics post 16 (I can only identify two).
As has been shown here, it is difficult to identify girls at an early age who are
going to choose to study physics post 16. Therefore, it would be interesting to
repeat this study, using just a narrative approach, and follow more girls who were
thinking o f studying physics during their pre-16 schooling in the hope that some
of them would actually choose physics.
257
More work also needs to be done to investigate how the school culture, within
which a girls’ identification with physics mainly develops, has an impact on that
identification. It would be helpful to carry out a more ethnographic approach to
the research by spending much more time following identified girls throughout
their school life seeing how they interact with their friends and peers, their
teachers and how the overall culture o f the school impacts on their daily life.
The Contribution of the Study
This research project was carried out to answer two research aims. These were:
1. to interrogate the current literature o f identity and self efficacy to develop
definitions o f physics identity and physics self efficacy and then to
develop a theoretical model linking the two
2. to explore what physics identity and physics self efficacy meant for girls
in school years 9-11 and produce narratives to examine how these impact
on future subject choices.
A theoretical framework has been proposed where self efficacy is believed to
form part o f identity and where identity is described as a process where we come
to think we know who we are, we think we know who others are, that they think
they know who we are and that we think we know who others think we are.
Identity work, or coming to recognise ourselves and others as certain types o f
people, is carried out in figured worlds. The choices we make, especially those
around what subjects to study post 16, are part o f us coming to know who we
are.
To explore how physics identity and physics self efficacy impact on future
subject choices o f girls in school years 9-111 used a mixed methods
methodology with a funnelling approach to selecting participants. Using this
approach I created four narratives which show four different trajectories o f
physics identity and show how differing factors affect those trajectories at
258
differing times. They illustrate how coming to understand physics choices needs
to be placed within the context o f an identification with physics.
Whilst carrying out the data collection, many o f the factors that have previously
been identified in the literature as impacting on choice were confirmed. Four new
contributions to the debate were identified. These were:
• teachers who are not physics specialists
• the discourse o f achievement
• similarity and differences between physics choosers and non choosers
• complexity and interrelationships o f figured worlds.
Evidence from the data to support these new contributions was discussed.
Overall, my research shows that tackling ‘the problem’ o f girls and physics can
only be done by taking an holistic view of how an individual’s identification with
physics develops within the wider worlds in which they live and by changing
many o f society’s views on physics and education in general.
Concluding Remarks
In Chapter 1 I introduced the reader to myself - who I am, who I think I am, and
who I think others think I am. My identity has changed during the time o f this
research; I have worked on my identity as a social scientist within the figured
world o f educational research. My trajectory has been an inbound one, but with
moments o f outbound movement when my self efficacy has been greatly
reduced.
I have been very fortunate that the girls I selected to talk to me in the small group
interviews were willing to share their thoughts and feelings about physics with
me. Without them I would not be able to make the contributions to move the
debate about ‘the problem’ o f girls and physics forward as I have done.
259
The issue o f how we attract more girls into physics is a complex one and needs
to be addressed, not by proposing quick fixes to ‘a problem’ that can be solved,
but by looking at the wider picture o f how physics forms a part o f the many
figured worlds that girls inhabit.
260
References
Acker, S. and Oatley, K. (1993). Gender issues in education for science and
technology: current situation and prospects for change. Canadian Journal
o f Education, 255-272.
Agar, M. (1996). The Professional Stranger: An Informal Introduction to
Ethnography. Academic Press.
Aikenhead, G. S. (1996). Science education: boarder crossing into the subculture
o f science. Studies in Science Education, 27, 1-52.
Aldridge, A. and Levine, K. (2001). Surveying the social world. Open University
Press, UK.
Andrews, M. (2007). Living counter-narratives. In C. Seale, G. Gobo, J. F.
Gubrium and D. Silverman (Eds). Qualitative Research Practice
(Chapter 6), Sage, Los Angeles.
Angell, C., Guttersrud, O., Henriksen, E. K. and Isnes, A. (2004). Physics:
frightful, but fun. Science Education, 88, 684-706.
Archer, L, Dewitt, J., Osborne, J., Dillon, J., Willis, B. and Wong, B. (2010).
“Doing” science versus “being” a scientist: examining 10/11-year old
schoolchildren’s constructions o f science through the lens o f identity.
Science Education, 94, 617-639.
Archer, L., DeWitt, J., Osborne, J., Dillon, J., Willis, B. and Wong, B. (2012).
“Balancing acts”: elementary school girls’ negotiations o f femininity,
achievement and science. Science Education, 96, 967-989.
Archer, L., DeWitt, J., Osborne, J., Dillon, J., Willis, B. and Wong, B. (2013).
‘Not girly, not sexy, not glamorous’: primary school girls’ and parents’
constructions o f science aspiration. Pedagogy, Culture and Society, 21,
171-194.
Aschbacher, P. R., Li, E. and Roth, E. J. (2010). Is science me? High school
students’ identities, participation and aspirations in science, engineering
and medicine. Journal o f Research in Science Teaching, 47, 564-582.
Aydeniz, M. and Hodge, L. L. (2011). Identity: a complex structure for
researching student’s academic behaviour in science and mathematics.
Cultural Studies o f Science Education, 6, 509-523.
262
Babbie, E. (1990). Survey research methods second edition. Wadsworth, USA.
Baker, D. and Leary, R. (2003). Letting girls speak out about science. Journal of
Research in Science Teaching, 40, S176-S200.
Bandura, A. (1982). Self-efficacy mechanism in human agency. American
Psychologist, 37, 122-147.
Baram-Tsabari, A. and Yarden, A. (2008). Girls’ biology, boys’ physics:
evidence from free-choice science learning settings. Research in Science
and Technological Education, 26, 75-92.
Baram-Tsabari, A. and Yarden, A. (2011). Quantifying the gender gap in science
interests. International Journal o f Science and Mathematics Education, 9,
523-550.
Barmby, P., Kind, P. M. and Jones, K. (2008). Examining changing attitudes in
secondary school science. International Journal o f Science Education,
30, 1075-1093.
Bennett, J. (2003). Teaching and Learning Science. Continuum, London.
Bennett, J. and Hogarth, S. (2009). Would you want to talk to a scientist at a
party? High school student’s attitudes to school science and to science.
International Journal o f Science Education, 31, 1975-1998.
Bennett, J., Lubben, F. and Hampden-Thompson, G. (2013). Schools that make a
difference to post-compulsory uptake o f physical science subjects: some
comparative case studies in England. International Journal o f Science
Education, 35, 663-689.
BERA. (2011). Ethical Guidelines fo r Educational Research, www.bera.ac.uk.
Betz, D. E. and Sekaquaptewa, D. (2012). My fair physicist? Feminine math and
science role models demotivate young girls. Social Psychological and
Personality Science, 3, 738-746.
Bhanot, R. T. and Jovanovic, J. (2009). The links between parent behaviours and
boys’ and girls’ science achievement beliefs. Applied Developmental
Science, 13, 42-59.
Blalock, C. L., Lichtenstein, M. J., Owen, S., Pruski, L., Marshall, C. and
Toepperwien, M. (2008). In pursuit o f validity: a comprehensive review
of science attitude instruments. International Journal o f Science
Education, 30, 961-977.
Blickenstaff, J. C. (2005). Women and science careers: leaky pipeline or gender
263
filter? Gender and Education, 17, 369-386.
Boaler, J., AltendorffL. and Kent G. (2011). Mathematics and science
inequalities in the United Kingdom: when elitism, sexism and culture
collide, Oxford Review o f Education, 37, 457-484.
Boaler, J. and Greeno, J. (2002). Identity, agency and knowing in mathematical
worlds. In J. Boaler (Ed). Multiple perspectives on mathematics teaching
and learning (p i71-200). Westport.
Boe, M. V. (2012). Science choices in Norwegian upper secondary school: what
matters? Science Education, 96, 1-20.
Boe, M. V., Henriksen, E. K. (2013). Love it o f leave it: Norwegian students’
motivations and expectations for postcompulsory physics. Science
Education, 97, 550-573.
Boe, M. V., Henriksen, E. K., Lyons, T. and Schreiner, C. (2011). Participation
in science and technology: young people’s achievement-related choices in
late-modern societies. Studies in Science Education, 47, 37-72.
Bohnsack, R. (2004). Group discussion and focus groups. In U. Flick, E von
Kardoff, and I. Steinke (Eds). A Companion to Qualitative Research.
Sage, London.
Bold, C. (2012) Using Narrative in Research, Sage, London.
Boylan, M. (2010). Ecologies o f participation in school classrooms. Teaching
and Teacher Education, 26, 61-70.
Breakwell, G. M., Vignoles, V. L. and Robertson, T. (2003). Stereotypes and
crossed-category evaluation: the case o f gender and science education.
British Journal o f Psychology, 94, 437-455.
Brickhouse, N. W., Lowery, P. and Schultz, K. (2000). What kind o f girl does
science? The construction o f school science identities. Journal o f
Research in Science Teaching, 37, 441-458.
Brickhouse, N. W. and Potter, J. T. (2001). Young women’s scientific identity
formation in an urban context. Journal o f Research in Science Teaching',
38, 965-980.
Britner, S. L. and Pajares, F. (2006). Sources o f science self efficacy beliefs o f
middle school students. Journal o f Research in Science Teaching, 43,
485-499.
Brooks, R. (2003). Young people’s higher education choices: The role o f family
264
and friends. British Journal o f Sociology o f Education, 24, 283-297.
Brotman, J. S. and Moore, F. M. (2008). Girls and science: a review o f four
themes in the science education literature. Journal o f Research in Science
Teaching, 45, 971-1002.
Bruner, J. (2004). Life as narrative. Social Research, 71, 691-710.
Buccheri, G., Abt Gurber, N. and Bruhwiler, C. (2011). The impact o f gender on
interest in science topics and the choice o f scientific and technical
vocations. International Journal o f Science Education, 33, 159-178.
Buck, G. A., Plano Clark, V. L., Leslie-Pelecky, D., Lu, Y. and Cerda-Lizarraga,
P. (2007). Examining the cognitive processes used by adolescent girls
and women scientists in identifying science role models: a feminist
approach. Science Education, 688-707
Carlone, H. B. (2012). Methodological considerations for studying identities in
school science : an anthropological approach. In M Varelas (Ed). Identity
construction and science education research. (Chapter 2). Sense,
Rotterdam.
Carlone, H. B., Haun-Frank, J. and Webb, A. (2011). Assessing equity beyond
knowledge and skills based outcomes: a comparative ethnography o f two
fourth-grade reform-based science classrooms. Journal o f Research in
Science Teaching, 48, 459-485.
Carlone, H. B. and Johnson, A. (2007). Understanding the science experiences o f
successful women o f color: science identity as an analytic lens. Journal o f
Research in Science Teaching, 44, 1187-1218.
Calabrese Barton, A. (1998). Teaching science with homeless children;
pedagogy, representation and identity. Journal o f Research in Science
Teaching, 35, 379-394.
Calabrese Barton, A. and Tan, E. (2009). Funds o f knowledge and discourses and
hybrid space. Journal o f Research in Science Teaching, 46, 50-73.
Calabrese Barton, A. and Tan, E. (2010). We be burning! Agency, identity and
science learning. Journal o f the Learning Sciences, 19, 187-229.
Calabrese Barton, A., Kang, H., O’Neill, T. B., Bautista-Guerra, J. and Brecklin,
C. (2013). Crafting a future in science: tracing middle school girls’
identity work over time and space. American Educational Research
Journal, 50, 37-75.
265
Catsambis, S. (1995). Gender, race, ethnicity and science education in the middle
grades. Journal o f Research in Science Teaching, 32, 243-257.
Clandinin, D. J. (2006). Narrative inquiry: a methodology for studying lived
experience. Research Studies in Music Education, 27, 44-54.
Clandinin, D. J. and Connelly, F. M. (2000). Experience and Story in Qualitative
Research. Jossey-Bass, San Francisco.
Cleaves, A. (2005). The formation o f science choices in secondary school.
International Journal o f Science Education. 27, 471-486.
Coe, R. J. (2012). The nature o f educational research. In J. Arthur, M. Waring, R.
Coe and L. V. Hedges (Eds). Research Methods and Methodologies in
Education (Chapter 2). Sage, London.
Connelly, F. M. and Clandinin, D. J. (1990). Stories o f experience and narrative
inquiry. Educational Researcher, 19, 2-14.
Creswell, J. W. (2003). Research Design (2nd edition). Sage Publications,
London.
Creswell, J. W. (2007). Qualitative Inquiry and Research Design (2nd Edition).
Sage Publications, London.
Cresswell, J. W. and Plano Clark, V. L. (2011) Designing and Conducting Mixed
Methods Research (2nd Edition). Sage, California.
Czamiawska, B. (2004). Narratives in Social Science Research. Sage
Publications, London.
Danielsson, A. T. (2012). Exploring woman university physics students ‘doing
gender’ and ‘doing physics’. Gender and Education, 24, 25-39.
Denscombe, M. (1995). Explorations in group interviews: an evaluation o f a
reflexive and partisan approach. British Educational Research Journal,
21, 131-148.
DeWitt, J., Archer, L. and Osborne, J. (2013). Nerdy, brainy and normal:
children’s and parents’ constructions o f those who are highly engaged
with science. Research in Science Education, 43, 1455-1476.
DeWitt, J., Osborne, J., Archer, L., Dillon, J., Willis, B. and Wong, B. (2013).
Young children’s aspirations in science: the unequivocal, the uncertain
and the unthinkable. International Journal o f Science Education, 35,
1037-1063.
DfE (2010) Science and mathematics data A-level statistics report.
266
DfE. (2012). Retrieved from
http://media.education.gov.Uk/assets/files/xls/s/sfrO 1 -2012t 13t 14.xls
DFEE (1997) Qualifying for success: a consultation paper on the future o f post-
16 qualifications.
DIUS. (2009).The Demand for STEM Graduates.
Eccles, J. (2009). Who am I and what an I going to do with my life? Personal and
collective identities as motivators o f action. Educational Psychologist,
44, 78-89.
Eccles, J., Adler, T. F., Fullerman, R., Goff, S. B., Kaezala, C. M., Meece, J. L.
and Midgely, C. (1983). Expectancies, values and academic behaviours, p
75-146 in Achievement and achievement motives: Psychological and
sociological approaches, Spence, J. T. Editor, Friedman, San Francisco.
Eccles, J., Barber, B. and Jozefowicz, D. (1999). Linking gender to educational,
occupational and recreational choices: applying the Eccles et al. model of
achievement-related choices, p i 53-192 in Sexism and stereotypes in
modern society: the gender science o f Janet Taylor Spence, Swan, W. B.,
Langlons, J. H. and Gilbert, L. A. Editors, American Psychological
Society, Washington DC.
Eccles, J., Vida, M. N. and Barber, B. (2004). The relation o f early adolescents’
college plans and both academic ability and task-value beliefs to
subsequent college enrolment. Journal o f Early Adolescence, 24, 63-77.
Fisher, D. and Rickards, T. (1998). Associations between teacher-student
interpersonal behaviour and student attitude to mathematics. Mathematics
Education Research Journal, 10, 3-15.
Flick, U. (2011). Introducing Research Methodology. Sage, London.
Flyvbjerg, B. (2007). Five misunderstandings about case-study research, p390-
404 in Qualitative Research Practice, Seale, C., Gobo, G., Gubrium, J. F.
and Silverman, D. Editors. Sage Publications.
Francis, B. (2000). The gendered subject: students’ subject preferences and
discussions o f gender and subject ability. Oxford Review o f Education,
26, 35-48.
Francis, B. (2010). Re/theorising gender: female masculinity and male femininity
in the classroom? Gender and Education, 22, 477-490.
Francis, B., Skelton, C. and Read, B. (2010). The simultaneous production of
267
educational achievement and popularity: how do some pupils accomplish
it? British Educational Research Journal, 36, 317-340.
Freire, S., Carvalho, C., Freire, A., Azevedo, M. and Oliveira, T. (2009). Identity
construction through schooling: listening to students’ voices. European
Educational Research Journal, 8, 80-88.
Frey, J. H. and Fontana, A. (1991). The group interview in social research. The
Social Science Journal, 28, 175-187.
Gee, J. P. (2000). Chapter 3: Identity as an analytical lens for research in
education. Review o f Research in Education, 25, 99-125.
Gilbert, J. and Calvert, S. (2003). Challenging accepted wisdom: looking at the
gender and science education question through a different lens.
International Journal o f Science Education, 25, 861-878.
Gill, T. (2012). Uptake o f GCEA level subjects 2011. Statistics Report Series No
42, Cambridge Assessment, Cambridge, UK.
Gilmartin, S., Denson, N., Li, E., Bryant, A. and Aschbacher, P. (2007). Gender
ratios in high school science departments: the effect of percent female
faculty on multiple dimensions o f students’ science identities. Journal o f
Research in Science Teaching, 44, 980-1009.
Golafshani, N. (2003). Understanding reliability and validity in qualitative
research. The Qualitative Report, 8, 597-607.
Gomm, R., Hammersley, M. and Foster, P. (2000). Eds. Case Study Method: Key
Issues, Key Texts. Sage, London.
Gonsalves, A. J. and Seiler, G. (2012). Recognising “smart super-physicists”:
gendering competence in doctoral physics. In M Varelas (Ed). Identity
construction and science education research. (Chapter 11). Sense,
Rotterdam.
Guba, E. G. (1990). The Paradigm Dialog. Sage, Newbury Park.
Guerra, J. B., Calabrese Barton, A., Tan, E., Kang, H. and Brecklin, C. (2012).
Kay’s coat o f many colors: out-of-school figured worlds and urban girls’
engagement with science. In M Varelas (Ed). Identity construction and
science education research. (Chapter 4). Sense, Rotterdam.
Hampden-Thompson, G., Lubben, F. and Bennett, J. (2011). Post-16 physics and
chemistry uptake: combining large-scale secondary analysis with in-depth
qualitative methods. International Journal o f Research and Method in
268
Education, 34, 289-307.
Hannover, B. and Kessels, U. (2004). Self-to-prototype matching as a strategy
for making academic choices. Why high school students do not like math
and science. Learning and Instruction, 14, 51-67.
Haste, H. (2004). Science in my future. Nestle Social Research Programme,
Report Number 1.
Haussler, P. and Hoffmann, L. (2002). An intervention study to enhance girls'
interest, self-concept and achievement in physics classes. Journal o f
Research in Science Teaching, 39, 870-888.
Hazari, Z., Sonnert, G., Sadler, P. M. and Shanahan, M-C. (2010). Connecting
high school physics experiences, outcome expectations, physics identity
and physics career choice: a gender study. Journal o f Research in Science
Teaching, 47, 978-1003.
Heller, K. A. and Ziegle, A. (1996). Gender differences in mathematics and the
sciences: can attributional retraining improve the performance o f gifted
females? Gifted Child Quarterly, 40, 200-210.
Hennink, M., Hutter, I. and Bailey, A. (2011). Qualitative Research Methods.
Sage, London.
Holland, D., Lachicotte, W., Skinner, D. and Cain, C. (1998). Identity and
Agency in Cultural Worlds. Harvard University Press, Cambridge,
Massachusetts.
Holland, D. and Lave, J. (2009). Social practice and the historical production o f
persons. Actio: An International Journal o f Human Activity Theory, 2, 1-
15.
Holmegaard, H. T., Ulriksen, L. M. and Madsen, L. M. (2012). The process o f
choosing what to study: a longitudinal study of upper secondary students’
identity work when choosing higher education. Scandinavian Journal o f
Educational Research, 1-20.
Holstein, J. A. and Gubrium, J. F. (1995). The active interview. Sage
Publications.
Hughes, G. (2001). Exploring the availability o f student scientist identities within
curriculum discourse: an anti-essentialist approach to gender-inclusive
science. Gender and Education, 13, 275-290.
Institute o f Physics. (2010). Engaging with Girls. London
269
Institute o f Physics. (2012). It's different for girls. London.
Institute o f Physics. (2013). Closing Doors. London.
Jackson, P. A. and Seiler, G. (2013). Science identity trajectories o f latecomers to
science in college. Journal o f Research in Science Teaching, 50, 826-857.
Jenkins, R. (2008). Social Identity (Third Edition). Routledge, London.
Jenkins, E. W. and Nelson, N. W. (2005). Important but not for me: students’
attitudes towards secondary school science in England. Research in
Science and Technological education, 23, 41-57.
Johnson, A., Brown, J., Carlone, H. and Cuevas, A. K. (2011). Authoring
identity amidst the treacherous terrain o f science: a multiracial feminist
examination o f the journeys o f three women o f color in science. Journal
o f Research in Science Teaching, 48, 339-366.
Jones, M. G., Howe, A. and Rua, M. J. (2000). Gender differences in students’
experiences, interests, and attitudes toward science and scientists. Science
Education, 84, 180-192.
Kaminski, D. M. (1982). Girls and mathematics and science. An annotated
bibliography o f British work (1970-1981). Studies in Science Education,
9, 81-108.
Kane, J. M. (2012a). Multiple identities and the science self: how a young
African American boy positions himself in multiple worlds. In M Varelas
(Ed). Identity construction and science education research. (Chapter 3).
Sense, Rotterdam.
Kane, J. M. (2012b). Young African American children constructing academic
and disciplinary identities in an urban science classroom. Science
Education, 96, 457-487.
Kelly, A. (1988). Gender differences in teacher-pupil interactions: a meta-
analytic review. Research in Education, 39, 1-24.
Kenway, J. and Gough, A. (1998). Gender and science education in schools: a
review ‘with attitude’. 1-29.
Kessels, U., Rau, M. and Hannover, B. (2006). What goes well with physics?
Measuring and altering the image o f science. British Journal o f
Educational Psychology, 16, 761-780.
Kozoll, R. H. and Osborne, M. D. (2004). Finding meaning in science: lifeworld,
identity and self. Science Education, 88, 157-181.
270
Krogh, L. B. and Thomsen, P. V. (2005). Studying students’ attitudes towards
science from a cultural perspective but with a quantitative methodology:
border crossing into the physics classroom. International Journal of
Science Education, 25, 281-302.
Kvale, S. (1996). Interviews An introduction to qualitative research interviewing.
Sage Publications.
Kvale, S. and Brinkmann, S. (2009). Interviews (2nd Edition). Sage Publications.
Lapadat, J. C. and Lindsey, A. C. (1999). Transcription in research and practice
from standardization o f technique to interpretive positioning. Qualitative
Inquiry, 5, 64-86.
Ladubbe, P., Herzog, W., Neuenschwander, M. O., Violi, E. and Gerber, C.
(2000). Girls and physics: teaching and learning strategies tested by
classroom interventions in grade 11. International Journal o f Science
Education, 22, 143-157.
Lave, J. and Wenger, E. (1991). Situated learning Legitimate peripheral
participation. Cambridge University Press, UK.
Levy, J., Brok, P. D., Wubbels, T. and Brekelmans, M. (2003). Students’
perceptions o f interpersonal aspects o f the learning environment.
Learning Environments Research, 6, 5-36.
Lyons, T. (2006). Different countries, same science classes: students’
experiences o f school science in their own words. International Journal
o f Science Education, 28, 591-613.
McAteer, M. (2000). Contempory science education: some historical and
philosophical roots. Unpublished DPhil theses. University o f Ulster.
Macnaughten, P. and Myers, G. (2007). Focus groups. In C. Seale, G. Gobo, J. F.
Gubrium and D. Silverman (Eds). Qualitative Research Practice
(Chapter 4), Sage, Los Angeles.
Manthorpe, C. A. (1982). Men’s science, women’s science or science? Some
issues related to the study o f girls’ science education. Studies in Science
Education, 9, 65-80.
Masnick, A. M., Valenti, S. S., Cox, B. D. and Osman, C. J. (2010). A
multidimensional scaling analysis o f students’ attitudes about science
careers. International Journal o f Science Education, 32, 653-667.
Mendick, H. (2003). Telling choices: an exploration o f the gender imbalance in
271
participation in advanced mathematics courses in England. Unpublished
PhD thesis, Goldsmiths College, University o f London.
Mendick, H. (2006). Masculinities in mathematics. Open University press.
England.
Meece, J. L. and Jones, M. G. (1996). Gender differences in motivation and
strategy use in science: are girls rote learners? Journal o f Research in
Science Teaching, 33, 393-406.
Miller, P. H., Slawinski Blessing, J. and Schwartz, S. (2006). Gender differences
in high-school students’ views about science. International Journal o f
Science Education, 28, 363-381.
Mujtaba, T. and Reiss, M. J. (2012a). Factors affecting whether students in
England choose to study physics once the subject is optional. NARST
March 2012, Indianapolis, USA.
Mujtaba, T. and Reiss, M. J. (2012b). What sort o f girls wants to study physics
after the age o f 16? Findings from a large-scale UK survey. International
Journal o f Science Education, 1 -20.
Murphy, P. and Whitelegg, E. (2006a). Girls in the physics classroom. Institute
o f Physics, London.
Murphy, P. and Whitelegg, E. (2006b). Girls and physics: continuing barriers to
‘belonging’. Curriculum Journal, 17, 281-305.
Olitsky, S. (2006). Structure, agency and the development o f students’ identities
as learners. Cultural Science Education, 1, 745-766.
Oliver, D. G., Serovich, J. M. and Mason, T. L. (2005). Constraints and
opportunities with interview transcription towards reflection in qualitative
research. Social Forces, 84, 1273-1289.
Ong, M. (2005). Body projects o f young women o f color in physics: intersections
o f gender, race, and science. Social Problems, 52, 593-617.
Osborne, J. and Collins, S. (2001). Pupils’ views of the role and value o f the
science curriculum: a focus-group study. International Journal o f Science
Education, 23, 441-467.
Osborne, J., Simon, S. and Collins, S. (2003). Attitudes towards science: a
review o f the literature and its implications. International Journal o f
Science Education, 25, 1049-1079.
Osborne, J., Simon, S. and Tytler, R. (2009). Attitudes towards science: a
212
update. Paper presented at the Annual Meeting o f the American
Educational Research Association, San Diego, California.
Pawson, R. (1999). Chapter 2 in Sociology: issues and debates edited by Taylor,
S. MacMillan, London.
Phipps, A. (2008). Women in Science, engineering and Technology three
decades o f UK initiatives. Trentham, Stoke on Trent, UK.
Pike, A. G. and Dunne, M. (2011). Student reflections on choosing to study
science post-16. Cultural Studies o f Science Education, 6, 485-500.
Price, J. F. and McNeill, K. L. (2013). Toward a lived science curriculum in
intersecting figured worlds: an exploration o f individual meanings in
science education. Journal o f Research in Science Teaching, 50, 501-529.
Quinn, F. and Lyons, T. (2011). High school students’ perceptions o f school
science and science careers: a critical look at a critical issue. Science
Education International, 22, 225-238.
Rahm, J. (2007). Youths’ and scientists’ authoring o f and positioning within
science and scientists’ work. Cultural Studies in Education, 1, 517-544.
Rahm, J. and Gonsalves, A. (2012). “To understand the news you need science!”
girls’ positioning and subjectivity in and beyond a newsletter activity in
and afterschool science program. In M Varelas (Ed). Identity construction
and science education research. (Chapter 5). Sense, Rotterdam.
Rapley, T. (2007). Chapter 1 Qualitative research practice edited by Seale, C.,
Gobo, G., Gubrium, J. F. and Silverman, D. Sage Publications.
Read, B., Archer, L. and Leathwood, C. (2003). Challenging cultures? Student
conceptions o f ‘belonging’ and ‘isolation’ at a post-1992 university.
Studies in Higher Education, 28, 261-277.
Reay, D. (2001). ‘spice girls’, ‘nice girls’, ‘girlies’, and ‘tomboys’: gender
discourses, girls’ cultures and femininities in the primary classroom.
Gender and Education, 13, 153-166.
Reay, D., David, M.E. and Ball, S. J. (eds) (2005). Degrees o f choice: social
class. Race and Gender in Higher Education. Trentham, Stoke on Trent.
Reay, D. and Wiliam, D. (1999). ‘I’ll be a nothing’: structure, agency and the
construction o f identity through assessment. British Educational
Research Journal, 25, 343-354.
Reid, N. and Skryabina, E. A. (2002). Attitudes towards physics. Research i
273
Science and Technological Education, 20, 67-81.
Reiss, M. J. (2004). Students’ attitudes towards science: a long-term perspective.
Canadian Journal o f Science, Mathematics and Technology Education, 4,
97-109.
Robson, C. (2002). Real World Research (2nd Edition). Blackwell, Oxford.
Rodd, M., Reiss, M. and Mujtaba, T. (2012). Undergraduates' stories about why
they are studying physics: implications fo r policy, ioe.ac.uk.
Rubin, B. C. (2007). Learner identity amid figured worlds: constructing
(in)competence at an urban high school. The Urban Review, 39, 217-249.
Ryan, L. M. (2012). ‘You must be very intelligent...?’: gender and science
subject uptake. International Journal o f Gender, Science and Technology,
4 167-190.
Ryan, G. W. and Bernard, H. R. (2003). Techniques to identify themes. Field
Methods, 15, 85-109.
Sawtelle, V., Brewe, E. and Kramer, L. H. (2012). Exploring the relationship
between self-efficacy and retention in introductory physics. Journal o f
Research in Science Teaching, 49, 1096-1121.
Schreiber, Z. (2011). Fizz nothing is as it seems. Zedess Publishing.
Schreiner, C. and Sjoberg, S. (2007). Science education and young people’s
identity construction - two mutually incompatible projects? In D,
Corrigan, J. Dillon and R. Gunstone (Eds). The Re-emergence o f Values
on Science Education. Sense, Rotterdam.
Schunk, D. H. and Meece, J. L. (2005). Self-efficacy development in
adolescences. In F. Paijares and T. C. Urdan (Eds). Self efficacy beliefs o f
adolescents (Chapter 3). Information Age Publishing.
Schwarzer, R. and Jerusalem, M. (1979). The general self-efficacy scale.
http://userpage.fii-berlin.de/~health/engscal.htm.
Sclater, S. D. (2007). Narrative and subjectivity. In C. Seale, G. Gobo, J. F.
Gubrium and D. Silverman (Eds). Qualitative Research Practice
(Chapter 6), Sage, Los Angeles.
Sfard, A. and Prusak, A. (2005). Telling identities: in search o f an analytic tool
for investigating learning as a culturally shaped activity. Educational
Researcher, 34, 14-22.
Shanahan, M-C. (2009). Identity in science learning: exploring the attention
274
given to agency and structure in studies o f identity. Studies in Science
Education, 45, 43-64.
Shanahan, M-C. and Nieswandt, M. (2011). Science student role: evidence of
social structural norms specific to school science. Journal o f Research i
Science Teaching, 48, 367-395.
Sikes, P. (2010). The ethics o f writing life histories and narratives in education
research. In A-M. Bathmaker and P. Harnett (Eds). Exploring learning,
identity and power through life history and narrative research (Chapter
2).Routledge, London.
Sikes, P. and Gale, K. (2006). Narrative approaches to educational research.
Faculty o f Education, University o f Plymouth.
Simpkins, S. D., Davis-Kean, P. E. and Eccles, J. S. (2006). Math and science
motivation: a longitudinal examination o f the links between choices and
beliefs. Developmental Psychology, 42, 70-83.
Sjaastad, J. (2011). Sources o f inspiration: the role o f significant persons in
young people’s choice o f science in higher education. International
Journal o f Science education, 34, 1-22.
Spall, K., Barrett, S., Stanisstreet, M., Dickson, D. and Boyes, E. (2003).
Undergraduates’ views about biology and physics. Research in Science
and Technological Education, 21, 193-208.
Spall, K., Stanisstreet, M., Dickson, D. and Boyes, E. (2004). Development o f
school students’ constructions o f biology and physics. International
Journal o f Science Education, 26, 787-803.
Squire, C., Andrews, M. and Tamboukan, M. (2008) Introduction to doing
narrative research. In C. Squire, M. Andrews, and Tamboukan, M. (Eds).
What is Narrative Research? Sage, London.
Stake, J. E. and Nickens, S. D. (2005). Adolescent girls’ and boys’ science peer
relationships and perceptions o f the possible self as scientist. Sex Roles,
52, 1-11.
Stewart, M. (1998). Gender issues in physics education. Educational Research,
40, 283-293.
Stokking, K. M. (2000). Predicting the choice o f physics in secondary education.
International Journal o f Science Education, 22, 1261-1283.
Taconis, R. and Kessels, U. (2009). How choosing science depends on students’
275
individual fit to ‘science culture’. International Journal o f Science
Education, 31, 1115-1132.
Tai, R. H., Qi Liu, C., Maltese, A. V. and Fan, X. (2006). Planning early for
careers in science. Science, 321, 1143-1144.
Tan, E. and Calabrese Barton, A. (2007). From peripheral to central, the story o f
Melanie’s metamorphosis in an urban middle school science class,
Science Education, 2, 1-24.
Tan, E. and Calabrese Barton, A. (2008). Unpacking science for all through the
lens o f identities in practice: the stories o f Amelia and Ginny. Cultural
Studies o f Science Education, 3, 43-71.
Tan, E. and Calabrese Barton, A. (2009). Transforming science learning and
student participation in sixth grade science: a case study o f a low-income,
urban, racial minority classroom. Equity and Excellence in Education, 43,
38-55.
Tenenbaum, H. R. and Leaper, C. (2003). Parent-child conversations about
science: the socialization o f gender inequities? Developmental
Psychology, 39, 34-47.
Thomas, G. (2011). How to do your Case S tu dy-A Guide for Students and
Researchers. Sage, London.
Thorley, A. D. M. (2010). Teaching influences on girls’ choices to study AS-level
physics. Dissertation for MRes award at Sheffield Hallam University.
Tobin, K., Deacon, J. and Fraser, B. J. (1989). An investigation o f exemplary
physics teaching. The Physics Teacher, 3, 144-150.
Tucker-Raymond, E., Varelas, M., Pappas, C. C. and Keblawe-Shamah, N.
(2012).Young children’s multimodal identity stories about being scientists. In M
Varelas (Ed). Identity construction and science education research.
(Chapter 6). Sense, Rotterdam.
UPMAP (2008). Understanding post-16 participation in mathematics and
physics. Institute o f Education London.
Usher, E. I. (2009). Sources o f middle school students’ self-efficacy in
mathematics: a qualitative investigation. American Educational Research
Journal, 46, 275-314.
Usher, R. (1996). Chapter 2 in Understanding Education Research edited by
276
Scott, D. and Usher, R. Routledge.
Varelas, M. Kane, J. M. and Wylie, C. D. (2011). Young African American
children’s representations o f self, science, and school: making sense o f
difference. Science Education, 95, 824-851.
Walshaw, M. (2005). Getting political and unravelling layers o f gendered
mathematical identifications. Cambridge Journal o f Education, 35, 19-
34.
Watson, L. C. and Watson-Franke, M. B. (1985). Interpreting life histories: and
anthropological inquiry. Rutgers University Press, USA.
Wenger (1998). Communities o f Practice. Cambridge University Press, UK.
Whitehead, J. M. (1996). Sex stereotypes, gender identity and subject choice at
A-level. Educational Research, 38, 147-190.
Wigfield, A. and Eccles, J. S. (2000). Expectancy-value theory o f achievement
motivation. Contemporary Educational Psychology, 25, 68-81.
Williams, C., Stanisstreet, M. Spall, K. Boyes, E. and Dickson, D. (2003). Why
aren’t secondary students interested in physics? Physics Education, 38,
324-329.
Willis, J. W. (2007). Foundations o f qualitative research interpretive and critical
approaches. Sage Publications.
Wong, B. (2012). Identifying with science : a case study o f two 130year-old
‘high achieving working class’ British Asian girls. International Journal
o f Science Education, 34, 43-65.
Woolnough, B. (1994). Why students choose physics or reject it. Physics
Education, 29, 368-374.
Wubbels, T. and Brekelmans, M. (1997). A comparison o f student perceptions o f
Dutch physics teachers’ interpersonal behaviour and their educational
opinions in 1984 and 1993. Journal o f Research in Science Teaching, 34,
447-466.
Wubbels, T. and Levy, J. (Eds) (1993) Do you know what you look like? Farmer
Press, London.
Yin, R. K. (2009). Case Study Research Design and Methods (4th Edition). Sage
Publications, USA.
Zhu, Z. (2007). Learning content, physics self efficacy and female students’
physics course taking. International Education Journal, 8, 204-212.
277
Appendices
Appendix 1. Year 9 Science Questionnaire
Year 9
Science Questionnaire
N a m e : - . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
T h i s q u e s t i o n n a i r e i s p a r t o f a s m a l l r e s e a r c h p r o j e c t i n v e s t i g a t i n g
t h e r e a s o n s w h y s o m e p e o p le s t u d y p h y s i c s a f t e r G C S E a n d o t h e r s d o
n o t .
Y o u r t e a c h e r s w i l l n o t s e e y o u r a n s w e r s . O n l y D e b o r a h ( t h e
r e s e a r c h e r ) w i l l s e e y o u r in d i v i d u a l a n s w e r s . A n y r e s u l t s u s e d f r o m
t h e s e q u e s t i o n n a i r e s w i l l b e r e p o r t e d s o t h a t in d i v i d u a l s t u d e n t s
c a n n o t b e i d e n t i f i e d .
Y o u h a v e b e e n a s k e d t o w r i t e y o u r n a m e o n t h e q u e s t i o n n a i r e . T h i s i s
s o t h a t D e b o r a h c a n i d e n t i f y p u p i l s t h a t s h e c a n i n v i t e t o t a k e p a r t in
a n o t h e r p a r t o f t h e r e s e a r c h .
T h e q u e s t i o n n a i r e s h o u l d o n ly t a k e y o u a b o u t 1 5 m i n u t e s t o c o m p l e t e .
H o p e f u l l y , y o u w i l l a n s w e r a l l t h e q u e s t i o n s , b u t i f y o u d o n ' t w a n t t o
a n s w e r a q u e s t i o n y o u d o n ' t h a v e t o .
278
Section 1 Subject Choices
Q 1 G C S E C h o i c e s
W h i c h s u b j e c t s h a v e y o u c h o s e n t o t a k e f o r G C S E n e x t y e a r ?
Q 2 F u t u r e S t u d i e s
A / A r e y o u i n t e n d i n g t o c o n t i n u e y o u r s t u d i e s a f t e r t h e a g e o f 1 6 ?
Y E S □ g o t o C
N O / N O T S U R E □ g o t o B
B / I f N o / N o t s u r e , p l e a s e e x p l a i n w h y y o u a r e n o t / n o t s u r e .
279
C i / H a v e y o u c o n s i d e r e d s t u d y i n g P h y s i c s a t A S / A ' I e v e l ?
Y E S N O
P l e a s e e x p l a i n y o u r a n s w e r .
C i i / W h a t a r e t h e s u b j e c t s t h a t y o u a r e m o s t l i k e l y t o t a k e a f t e r
y o u r G C S E s ? P l e a s e l i s t t h e m in o r d e r o f p r e f e r e n c e w i t h t h e m o s t
l i k e l y f i r s t a n d g i v e a r e a s o n f o r y o u r c h o i c e ( e .g . i n t e r e s t e d in
s u b j e c t , n e e d f o r f u t u r e c a r e e r , l i k e t e a c h e r , f r i e n d s d o in g s a m e
s u b j e c t , a n y t h i n g e l s e ) .
S u b j e c t R e a s o n
280
281
Section 2 Science a t School
Q 3 S c i e n c e T o p i c s
L i s t e d b e l o w a r e s o m e t o p i c s y o u h a v e s t u d i e d r e c e n t l y in s c i e n c e
c l a s s e s .
P l a c e a t i c k in t h e b o x n e x t t o y o u r f a v o u r i t e 3 t o p i c s .
T o p i c
G l o b a l w a r m in g
P h o t o s y n t h e s i s
R e a c t i v i t y o f m e t a l s
M o m e n t s
P r e s s u r e
S e l e c t i v e b r e e d i n g
W h i c h w a s y o u r l e a s t f a v o u r i t e t o p i c a n d w h y ?
282
R e a d t h e f o l l o w i n g s t a t e m e n t s t h e n t i c k a b o x t o i n d i c a t e w h e t h e r
y o u a g r e e , d i s a g r e e o r n e i t h e r a g r e e n o r d i s a g r e e w i t h e a c h
s t a t e m e n t a b o u t s c i e n c e a t s c h o o l .
Q 4 Science Lessons
A g r e e N e i t h e ra g r e en o rd i s a g r e e
D i s a g r e e
1 lo o k f o r w a r d t o s c i e n c e l e s s o n s
1 n m y s c i e n c e l e s s o n s , m y t e a c h e r s e x p l a i n h o w s c i e n c e i d e a s c a n b e a p p l i e d t o a n u m b e r o f d i f f e r e n t s i t u a t i o n sI n m y s c i e n c e l e s s o n s , 1 h a v e t h e
o p p o r t u n i t y t o d i s c u s s m y i d e a s a b o u t s c i e n c e
1 e n j o y m y s c i e n c e l e s s o n s
1 l e a r n n e w s k i l l s in s c i e n c e l e s s o n s
1 e n j o y d o in g p r a c t i c a l w o r k in s c i e n c e l e s s o n s
1 l i k e m y s c i e n c e t e a c h e r s
283
0)oc0O</>
T30)4-1(/)au0)
s_0
.3Oca0
I -0u30
'a( /)
00co4-Jo0
( /)
0uoE0E0
J *<oEcoL.0
£ara0* j
0Oc0a<o
I*IX)a
0co3cao0
.Q00L_CO0CO
>>L_0>
0-X
E
I f■° ti S' £SZ 0
£
0
4->0
3o 0Q_ O0 a)4->00CO
3o
*a
aco
co3o
T 301_0
E4-J0
■a304->COL_0
■a334->~3o
•a
0coCOl_0szo004-J0oc0
’oCO
■M0
0CO0CO00
cOCO00i_i_0SZ4->O30
00L_CD0CO
O300i_CD 0 :L -0 0
.C CO30a0n
co0sz0o30
‘oCO4->3O
.Q0
0
i£
0o30)
‘aCO
E34-J£O
■ao4-JCD
_c30
.33 a4-J 0O 03 4-J
0CO0CO00Q .I
3oCO00i_L_0
.3O30
4->0
0CO30O0JQ00i_CD0
O -§
■r co 0 .2> 4-J0 *>CO 4-J 3 U 0
oT 3 (U0 ”25 ‘co
4-> 3 O0
4->0
4-J3
0 *5) §
I t
o o3 4-J(U COF 03 4-J£ iSO 0CO 00 0
‘oCO
o4-JCO0‘co3
.34-J300i_0
0
00OCOCD3'sz4—*3]caQ.X0>>0
3In4-J0E0St0E>>0
0CO0CO0_0Cli
3OCO00L.L_0SZo -M§ 5
284
inooCN
Section 4 About Physics
Q 6 B e l o w a r e s o m e w o r d s t h a t d e s c r i b e h o w I f e e l a b o u t p h y s i c s .
C i r c l e a n y w o r d s t h a t f i t y o u a n d a d d s o m e o t h e r w o r d s i f y o u w o u ld
l i k e .
E n j o y L i k e H a t e B o r e d
F r i g h t e n e d E x c i t e d A n x i o u s
W o r r i e d D i f f i c u l t E a s y I n t e r e s t i n g
Q 7 C o m p l e t e t h e f o l l o w i n g s e n t e n c e s .
a / I f I d o n ' t u n d e r s t a n d s o m e t h i n g in p h y s i c s I c a n g e t h e l p f r o m
b / I f a t o p i c in p h y s i c s i s h a r d I
Q 8 R e a d t h e f o l l o w i n g s t a t e m e n t s a b o u t y o u a n d p h y s i c s . T i c k t h e
o n e s t h a t a p p l y t o y o u .
I n m y c l a s s , 1 a m o n e o f t h e b e s t a t p h y s i c s
I n m y c l a s s , 1 a m a b o u t t h e s a m e a s m o s t p e o p le a t p h y s i c s
1 n m y c l a s s , 1 a m o n e o f t h e w o r s t a t p h y s i c s
1 l i k e p h y s i c s m o r e t h a n m y f r i e n d s
286
I l i k e p h y s i c s a b o u t t h e s a m e a s m y f r i e n d s
I l i k e p h y s i c s a l o t l e s s t h a n m y f r i e n d s
Q 9 I f y o u w e r e a s k e d t o d e s c r i b e a p h y s i c i s t , w h a t w o u ld y o u s a y ?
Q 1 0 P e o p l e c a n b e d e s c r i b e d a s 'a p h y s i c s s o r t o f p e r s o n ' . D o y o u
t h i n k y o u a r e a p h y s i c s s o r t o f p e r s o n o r n o t ? E x p l a i n y o u r a n s w e r .
287
Q 1 1 A r e y o u m a l e o r f e m a l e ? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Q 1 2 W h e r e d o y o u l i v e ? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Q 1 3 W h a t i s y o u r e t h n i c i t y ? P l e a s e t i c k o n e b o x
W h i t e □
B l a c k □
A s i a n □
M i x e d R a c e □
O t h e r □
Section 5 About You
Q 1 4 W h a t a r e y o u r p a r e n t s ' / c a r e r s ' o c c u p a t i o n s ? P l e a s e t i c k o n e
b o x f o r e a c h p a r e n t / c a r e r .
M o t h e r o r
C a r e r 1
F a t h e r o r
C a r e r 2
P r o f e s s i o n a l e.g. doctor, dentist, teacher, nurse,
manager
C l e r i c a l a n d s k i l l e d n o n - m a n u a l e.g. secretary,
clerk, typist, receptionist, Local Government
employee (administrative/clerical)
S e n i o r o f f i c i a l e.g. police, fire, prison or
ambulance officer, immigration or custom officer,
surveyor
S t o r e w o r k e r e.g. sales rep, shop worker
S k i l l e d m a n u a l w o r k e r e.g. plumber, electrician,
fitter, chef, bus driver
S e m i - s k i l l e d m a n u a l w o r k e r e.g. hairdresser,
caretaker, childcare worker
288
U n s k i l l e d w o r k e r e.g. labourer, window cleaner,
cleaner, bar staff
D o n ' t k n o w
U n e m p l o y e d
T h a n k y o u f o r c o m p l e t i n g t h i s s h o r t q u e s t i o n n a i r e .
W o u l d y o u b e w i l l i n g t o t a k e p a r t in a s m a l l g r o u p i n t e r v i e w t o t a l k
a b o u t y o u r f u t u r e s u b j e c t c h o i c e s a n d y o u r f e e l i n g s a b o u t p h y s i c s
a n d p h y s i c s l e s s o n s ?
Y E S □ N O □
289
Year 10
Physics Questionnaire
Appendix 2 Year 10 Physics Questionnaire
N a m e : - . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
T h i s q u e s t i o n n a i r e i s p a r t o f a s m a l l r e s e a r c h p r o j e c t i n v e s t i g a t i n g
t h e r e a s o n s w h y s o m e p e o p le s t u d y p h y s i c s a f t e r G C S E a n d o t h e r s d o
n o t .
Y o u r t e a c h e r s w i l l n o t s e e y o u r a n s w e r s . O n l y D e b o r a h ( t h e
r e s e a r c h e r ) w i l l s e e y o u r in d i v i d u a l a n s w e r s . A n y r e s u l t s u s e d f r o m
t h e s e q u e s t i o n n a i r e s w i l l b e r e p o r t e d s o t h a t in d i v i d u a l s t u d e n t s
c a n n o t b e i d e n t i f i e d .
Y o u h a v e b e e n a s k e d t o w r i t e y o u r n a m e o n t h e q u e s t i o n n a i r e . T h i s i s
s o t h a t D e b o r a h c a n i d e n t i f y p u p i l s t h a t s h e c a n i n v i t e t o t a k e p a r t in
a n o t h e r p a r t o f t h e r e s e a r c h .
T h e q u e s t i o n n a i r e s h o u l d o n ly t a k e y o u a b o u t 1 5 m i n u t e s t o c o m p l e t e .
H o p e f u l l y , y o u w i l l a n s w e r a l l t h e q u e s t i o n s , b u t i f y o u d o n ' t w a n t t o
a n s w e r a q u e s t i o n y o u d o n ' t h a v e t o .
290
S e c t i o n 1 S u b j e c t C h o i c e s
Q 1 G C S E C h o i c e s
W h i c h s u b j e c t s a r e y o u t a k i n g f o r G C S E ?
Q 2 F u t u r e S t u d i e s
A / A r e y o u i n t e n d i n g t o c o n t i n u e y o u r s t u d i e s a f t e r t h e a g e o f 1 6 ?
Y E S □ g o t o C
N O / N O T S U R E □ g o t o B
B / I f N o / N o t s u r e , p l e a s e e x p l a i n w h y y o u a r e n o t / n o t s u r e .
291
C i / H a v e y o u c o n s i d e r e d s t u d y i n g P h y s i c s a t A S / A ' l e v e l ?
Y E S N O
P l e a s e e x p l a i n y o u r a n s w e r .
C i i / W h a t a r e t h e s u b j e c t s t h a t y o u a r e m o s t l i k e l y t o t a k e a f t e r
y o u r G C S E s ? P l e a s e l i s t t h e m in o r d e r o f p r e f e r e n c e w i t h t h e m o s t
l i k e l y f i r s t a n d g i v e a r e a s o n f o r y o u r c h o i c e ( e .g . i n t e r e s t e d in
s u b j e c t , n e e d f o r f u t u r e c a r e e r , l i k e t e a c h e r , f r i e n d s d o in g s a m e
s u b j e c t , a n y t h i n g e l s e ) .
S u b j e c t R e a s o n
292
293
Section 2 Physics at School
Q 3 P h y s i c s T o p i c s
L i s t e d b e l o w a r e s o m e t o p i c s y o u h a v e s t u d i e d r e c e n t l y in p h y s i c s c l a s s e s .P l a c e a t i c k in t h e b o x n e x t t o y o u r f a v o u r i t e 2 t o p i c s .
T o p i c
S t a t i c e l e c t r i c i t y
E l e c t r o m a g n e t i c w a v e s
R a d i o a c t i v i t y
O r i g i n s o f t h e u n i v e r s e
W h i c h w a s y o u r l e a s t f a v o u r i t e t o p i c a n d w h y ?
294
R e a d t h e f o l l o w i n g s t a t e m e n t s t h e n t i c k a b o x t o i n d i c a t e w h e t h e r
y o u a g r e e , d i s a g r e e o r n e i t h e r a g r e e n o r d i s a g r e e w i t h e a c h
s t a t e m e n t a b o u t p h y s i c s a t s c h o o l .
Q 4 Physics Lessons
A g r e e N e i t h e ra g r e en o rd i s a g r e e
D i s a g r e e
1 lo o k f o r w a r d t o p h y s i c s l e s s o n s
I n m y p h y s i c s l e s s o n s , m y t e a c h e r s e x p l a i n s h o w a p h y s i c s i d e a c a n b e a p p l i e d t o a n u m b e r o f d i f f e r e n t s i t u a t i o n s1 n m y p h y s i c s l e s s o n s , 1 h a v e t h e
o p p o r t u n i t y t o d i s c u s s m y i d e a s a b o u t p h y s i c s
1 e n j o y m y p h y s i c s l e s s o n s
1 l e a r n n e w s k i l l s in p h y s i c s l e s s o n s
1 e n j o y d o in g p r a c t i c a l w o r k in p h y s i c s l e s s o n s
1 l i k e m y p h y s i c s t e a c h e r
295
</>o‘(75>%
■o0>4->(/)0)L.0)
COs_0.c(JCO0H(/)o'in
0i_oEa>Ea)co
</)ua>x;o(00)(/)o'<75 >»
COco4->o0GO
>»IEU)a
0in00O0n00i_CD0inTD
0>4-J0.x0E4->toT3
0)C4->in >*» 0
£ fc *i £
04->0
4-JCoQ- .E0x:4->00inco■D
in>>szClcCDc'o■O01_0
E4-J0
■a S'm in
t o i -L_ 0 0 -C ■O oC 0 0 04->“co•a
inoin >*» —: sz: CL
>>0in0in0 _0D.1
coin00L_I—0SZ4-JOc0
4-J0
00l_CD0ini_oc00l_CD00 0 in4-J0
00o0SZ
in0.cino
ino‘in
in Q_x: pCL C4-J SZ 0 4-J° > n >0 o® o <2 2 — CD C 0
J= o 4-J 0O 0 C 4-J
0in0in0 0ql1
coin00
0
° ti c: 0 0 x=
4-o o ■aS ' o4-J
o*o0
0
0;g ‘in4-J0O0
0in30o0n00i_CD0
■r to0 ®> tf 0 ’>in 4-J3 oCD4 =CD q)
l £: T3
^ O 5 4->o in sz 00 4-JE5 2 o cn xi o10 «S’ .S’2sz a- £r ^ c i
o4-Jin0'in0sz4-Jc001_0
0x:4-J
0_0ainCDc4-JC’_0CLX0
0
.Xc'sz-M0E00E>>0
0in0in00CL11coin00i_i_0SZ4-JO 4-Jc 00 XI
296
ON<N
Section 4 About Physics
Q 6 B e l o w a r e s o m e w o r d s t h a t d e s c r i b e h o w I f e e l a b o u t p h y s i c s .
C i r c l e a n y w o r d s t h a t f i t y o u a n d a d d s o m e o t h e r w o r d s i f y o u w o u ld
l i k e .
E n j o y L i k e H a t e B o r e d
F r i g h t e n e d E x c i t e d A n x i o u s
W o r r i e d D i f f i c u l t E a s y I n t e r e s t i n g
Q 7 C o m p l e t e t h e f o l l o w i n g s e n t e n c e s .
a / I f I d o n ' t u n d e r s t a n d s o m e t h i n g in p h y s i c s I c a n g e t h e l p f r o m
b / I f a t o p i c in p h y s i c s i s h a r d I
Q 8 R e a d t h e f o l l o w i n g s t a t e m e n t s a b o u t y o u a n d p h y s i c s . T i c k t h e
o n e s t h a t a p p l y t o y o u .
1 n m y c l a s s , 1 a m o n e o f t h e b e s t a t p h y s i c s
I n m y c l a s s , 1 a m a b o u t t h e s a m e a s m o s t p e o p le a t p h y s i c s
I n m y c l a s s , 1 a m o n e o f t h e w o r s t a t p h y s i c s
1 l i k e p h y s i c s m o r e t h a n m y f r i e n d s
298
I l i k e p h y s i c s a b o u t t h e s a m e a s m y f r i e n d s
I l i k e p h y s i c s a l o t l e s s t h a n m y f r i e n d s
Q 9 I f y o u w e r e a s k e d t o d e s c r i b e a p h y s i c i s t , w h a t w o u ld y o u s a y ?
Q 1 0 P e o p l e c a n b e d e s c r i b e d a s 'a p h y s i c s s o r t o f p e r s o n ' . D o y o u
t h i n k y o u a r e a p h y s i c s s o r t o f p e r s o n o r n o t ? E x p l a i n y o u r a n s w e r .
299
S e c t i o n 5 A b o u t Y o u
Q 1 1 A r e y o u m a l e o r f e m a l e ? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Q 1 2 W h e r e d o y o u l i v e ? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Q 1 3 W h a t i s y o u r e t h n i c i t y ? P l e a s e t i c k o n e b o x
W h i t e □
B l a c k □
A s i a n □
M i x e d R a c e □
O t h e r □
Q 1 4 W h a t a r e y o u r p a r e n t s ' / c a r e r s ' o c c u p a t i o n s ? P l e a s e t i c k o n e
b o x f o r e a c h p a r e n t / c a r e r .
M o t h e r o r
C a r e r 1
F a t h e r o r
C a r e r 2
P r o f e s s i o n a l e.g. doctor, dentist, teacher, nurse,
manager
C l e r i c a l a n d s k i l l e d n o n - m a n u a l e.g. secretary,
clerk, typist, receptionist, Local Government
employee (administrative/clerical)
S e n i o r o f f i c i a l e.g. police, fire, prison or
ambulance officer, immigration or custom officer,
surveyor
S t o r e w o r k e r e.g. sales rep, shop worker
S k i l l e d m a n u a l w o r k e r e.g. plumber, electrician,
fitter, chef, bus driver
S e m i - s k i l l e d m a n u a l w o r k e r e.g. hairdresser,
300
caretaker, childcare worker
U n s k i l l e d w o r k e r e.g. labourer, window cleaner,
cleaner, bar staff
D o n ' t k n o w
U n e m p l o y e d
T h a n k y o u f o r c o m p l e t i n g t h i s s h o r t q u e s t i o n n a i r e .
W o u l d y o u b e w i l l i n g t o t a k e p a r t in a s m a l l g r o u p i n t e r v i e w t o t a l k
a b o u t y o u r f u t u r e s u b j e c t c h o i c e s a n d y o u r f e e l i n g s a b o u t p h y s i c s
a n d p h y s i c s l e s s o n s ?
Y E S □ N O □
301
Appendix 3. Coding for Questionnaire Tall versions)
Throughout missing answer = 99
Student ID - number on front o f questionnaire
School
Balcarras = 0
Harrogate = 1
Year
Year 9 = 0
Year 10 = 1
Q2
Yes = 0
No = 1
Q2ci
Yes = 0
No = 1
Reasons Career = 1
Interesting/Enjoy = 2
Don't enjoy/Boring = 3
Not needed for fixture = 4
No reason = 5
Not good at subject = 6
Other = 7
Q2cii (5 entries)
Physics = 0
Chemistry = 1
Biology = 2
Maths = 3
302
Further maths = 4
ICT/Computing = 5
English = 6
History = 7
Geography = 8
Art = 9
Drama = 10
PE = 11
Health and Social Care = 12
Psychology = 13
Sociology = 14
Photography = 15
Politics = 16
Economics = 17
Other = 18
French =19
German = 20
Spanish = 21
03 (4 entries - 3 positive and 1 negative)
Static electricity = 0
Electromagnetic waves = 1
Radioactivity = 2
Origins o f universe = 3
Global warming = 4
Inheritance = 5
Radiation = 6
Energy transfers = 7
Habitats = 8
Photosynthesis = 9
Reactivity o f metals = 10
Moments =11
Pressure = 12
Selective breeding =13
303
0 4 (7 entries")
Agree = 0
Neither agree nor disagree = 1
Disagree = 2
05.Agree - different activities = 0
Agree - relates to outside world = 1
Agree - enthusiastic = 2
Agree - explain clearly = 3
Agree - make me think = 4
Agree - other = 5
Agree - more than one answer = 6
Neither agree nor disagree - nothing to do with teachers = 7
Neither agree nor disagree - other = 8
Neither agree nor disagree - more than one answer = 9
Disagree - don’t make it interesting = 10
Disagree - don’t see point in physics =11
Disagree - don’t understand teachers =12
Disagree - other =13
Disagree - more than one answer = 14
Confused answer = 88
0 6 (5 entries)
Enjoy = 0
Like = 1
Hate = 2
Bored = 3
Frightened = 4
Excited = 5
Anxious = 6
Worried = 7
Difficult = 8
Easy = 9
304
Interesting = 10
Other =11
07a (2 entries)
Friends = 0
Teachers = 1
Book = 2
Internet = 3
Family = 4
Other = 5
07b (2 entries)
Ask friends = 0
Ask teachers = 1
Ask family = 2
Look in book = 3
Look on internet = 4
Don’t do anything = 5
Think = 6
Work it out = 7
Other = 8
08a
I am one o f the best = 0
I am the same = 1
I am worst = 2
08b
Like more = 0
Like same = 1
Like less = 2
Q U
Male = 0
305
Female = 1
013
White = 0
Black = 1
Asian = 2
Mixed race = 3
Other = 4
014
Professional = 0
Clerical and skilled non-manual
Senior official = 2
Store worker = 3
Skilled manual = 4
Semi-skilled manual = 5
Unskilled = 6
Don’t know = 7
Unemployed = 8
Appendix 4 Physics Words Word Cloud Figures
Girls who are thinking o f choosing A-level physics (n=41)
Word Number
Enjoy 8
Like 19
Hate 4
Bored 19
Frightened 1
Excited 1
Anxious 2
Worried 3
Difficult 18
Easy 6
Interesting 26
Other 12
Bovs who are thinking o f choosing A-level physics (11=135)
Word Number
Enjoy 71
Like 76
Hate 5
Bored 26
Frightened 5
Excited 22
Anxious 2
Worried 1
Difficult 24
Easy 48
Interesting 106
307
Other 16
Girls who are not thinking o f choosing A-level physics (11=1581
Word Number
Enjoy 7
Like 27
Hate 43
Bored 104
Frightened 10
Excited 1
Anxious 12
Worried 16
Difficult 111
Easy 8
Interesting 38
Other 53
Bovs who are not thinking o f choosing A-level physics (n=l 191
Word Number
Enjoy 17
Like 26
Hate 21
Bored 70
Frightened 11
Excited 6
Anxious 14
Worried 16
Difficult 47
Easy 13
308
Interesting 42
Other 27
309
Appendix 5. Interviewees Questionnaire Responses
A-level subject choices
The girls chosen for the interviews had selected a wide range o f possible subjects
to study for A-level.
O f course, since I had selected all the girls who were going to choose physics
who were willing to be interviewed for the group interviews, this chart shows a
much higher than average number o f girls choosing physics. I therefore
investigated what subjects these physics choosers were going to choose along
side physics. In my MRes research (Thorley, 2010), I had found that physics
choosers could be split into two groups; those who were following a traditional
science programme and those who had chosen physics in a more mixed A-level
programme.
310
Other Subejcts for Interveiwees who are Physcis Choosers
n n
. 1 ■ 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I<c* Q<p ^
As can be seen a very wide range of other subjects were chosen to accompany
physics by the 19 physics choosers selected for the group interviews. The most
popular subject to accompany physics is maths with 12 girls choosing this
followed by chemistry by 9, biology by 6 then history and geography with 5.
However the wide range of subjects shows that physics is not only chosen as part
o f a mainly science A-level programme as has been traditional in the past but is
included in many mixed A-level programmes. The Department o f Education
report (2010) looking at A-level statistics reported that for A-level science
entrants, 57% took one science subject, 38% took two science subjects and just
5% took three science subjects. Of these groupings, 48% of the one science
group also took mathematics, 59% of the two science group also took
mathematics and 48% of the three science group also took mathematics. The
report also showed that the most common subjects that were combined with
mathematics and/or science at A-level were general studies, further mathematics,
history and geography. These results focus on science subjects in general and do
not differentiate by subject. However, it must be remembered that this subject
selection is only at the proposed stage and these subjects may not actually be
chosen for A-levels when the time comes.
311
Reasons for choosing or not choosing physics
10
9
8
7
6
03f 53z
4
3
2
1
0
For the 19 girls in my interview cohort who are thinking of choosing physics the
main reason for doing so is linked to a future career with the second reason
because they enjoy the subject. This is the same trend as for all the girls who
completed the questionnaire (see chapter 5).
Reasons for Choosing Physics
1__ —Good at physics For future career Enjoy physics Physcis is maths based Like all sciences
312
12 ------------------------------------------------------------
10 ------------------------------------------------------
8----------------------------------------- I-------------------------------------------------------■-QE I ■ ------------------3
z6 ----------------------------------------------------------
4 ---------------- -------------------- ------------------------------- ------------------------------ ----------------------------------------------------------
2 ----------------------------------------------------------
0 -I ----------- 1- —---------- ,------- ,------- 1—----——---Physics is hard Not needed for future career Do no enjoy physics No reason
For those girls in the interview cohort who are not thinking o f choosing physics
the main reason is that they do not think that they will need physics for a future
career. This again is the same as for all the girls who completed the questionnaire
(see chapter 5).
For both choosers and none choosers of physics, future career aspirations are
important and linked closely to future subject choices. (refBoe et al (2012); Pike
and Dunne, 2011).
Words to describe physics
Interviewees who are thinking o f choosing physics
Reasons for not Choosing Physics
14 ---- --------------------------------------------------------------- ----- -------------------
313
CD &
*
gt interestingM-} <: o 9 : lil/pI—K ^ XI— • § O —
g o §, 2 l easy
Overall as expected the most chosen word to describe physics by those girls who
are going to choose physics is interesting. However, this is closely followed by
bored and difficult, two words that I did not expect to feature so highly for
choosers o f physics.
Since I had not expected girls who were thinking o f choosing physics to describe
it as boring and/or difficult, I looked more closely at the girls who had chosen
these words to describe physics. I looked at what other words they had chosen
and the reason they gave for choosing physics to see if any other patterns
emerged.
Boring Difficult Other words Reason
YES YES Career
YES YES Career
YES YES Career
YES YES Career
YES YES Interesting Interesting
YES YES Interesting Interesting
314
YES Like, interesting Interesting
YES Like, interesting Maths based
YES Like, interesting Career
YES Enjoy physics
YES Interesting, hate Like all sciences
YES Like, interesting Career
YES Like, interesting Enjoy physics
Of the 13 girls who had selected either or both bored and difficult as words to
describe physics, six had chosen physics because of their future career. Seven o f
the girls had linked interesting with either bored or difficult.
Interviewees who are not thinking o f choosing physics
worriedc o n f u s i n g
1 i d i f f i c u l f J0y°-5 s . ^interesting
CTQ
For the none physics choosers the most common words selected to describe
physics were bored and difficult followed by like and interesting. Those girls
who said they liked physics or found it interesting were not choosing physics
because they did not need it for a future career (6 girls); because they felt physics
was hard (3 girls); because they did not enjoy it (2 girls) or they did not give a
reason (1 girl).
When selecting words to describe physics there are examples in both the
choosers and none choosers where words that could be considered to be
contradictory have been selected together and then where the overall reason for
choosing physics is contradictory again.
For interviewees who were either choosers or none choosers o f physics, overall
future career appears to be a strong influencer as to whether to choose physics or
not. Six girls who were thinking o f choosing physics described the subject as
boring and/or difficult whereas six girls who were not thinking o f choosing
physics described it as interesting. Boe et al (2011), using aspects of Eccles et al
316
(1983) choice model, describe the unity value of STEM subjects where students
will choose one o f these subjects because it will help them towards their goal o f a
future career even if they find the subject difficult or uninteresting. However,
they found that girls who chose STEM subjects in this way were especially
worried about failure in that subject. Conversely, girls who found physics
interesting did not think of choosing it because they did not see a link between
physics and their future career. This agrees with Pike and Dunne’s (2011) and
Cleaves’ (2005) findings where students did not choose to pursue subjects that
did not fit with their future career pathways.
Physics self efficacy
As described in chapter 3, previous research has shown that self efficacy can be
used as a predictor of future subject uptake (Britner and Pajares, 2006). The
higher the self efficacy the more likely someone is to choose that subject.
Self Efficacy for choosers
5
4
□ B9
B B10□ H9
□
oX
2
1
0 4_i— --------— —,— — — — —,------------------------ ,— — — — —,— — — —,------- mm-----------One of the best About the same One of the worst Like more than friends Like the same Like less than friends
317
Self Efficacy for Non choosers
8 -------
1
V H 1
□ B9
■ B10
□ H9□ H10
One of the best About the same One of the worst Like more than friends Like the same Like less than friends
The majority o f girls selected for the group interviews report a neutral self
efficacy, that is they are the same as the rest o f the class for their physics ability
and they like physics the same as their friends. Only two interviewees report a
high self efficacy for their physics ability and they are both choosers of physics.
Ten girls recorded a high self efficacy for liking physics more than their friends.
Six o f these girls are physics choosers but four are not. Looking at the reasons
why these four girls did not choose physics three said that they did not need it for
their future career and one that she found physics hard. Looking at low self
efficacy three girls felt that they were one the worst in their class for physics and
they were all none choosers. Seven girls said that they liked physics less than
their friends and six o f these were none choosers. This means that one girl who
likes physics less than her friends has still chosen to take it for A-level. Her
reason for this is that she needs it for her future career. This is another example
o f future career greatly influencing future subject choice. Therefore, from this
sample, it appears that just having a high physics self efficacy with respect to
liking physics more than your friends does not predict future subject choices as
suggested by the work o f Britner and Pajares (2006) or Porter (2011). Future
career aspirations appear to have a stronger influence on choice. The same can be
said for the one girl who displayed a low physics self efficacy with respect to
liking physics less than her friends who would have not been predicted to choose
318
physics by her reported self efficacy alone but who was doing so because o f the
value placed on it to help her enter her future chosen career.
319
Appendix 6. Interview Schedules
1/ Introductions and outline o f project
2/ Let’s talk about science/physics at school
What do you think o f it?
Best/worst topics or aspects o f science/physics lessons - do you all
agree/disagree
3/ My project is all about future subject choices - what you are going to do for
AS/A-level and beyond. Can you tell me about your choices and how you have
decided on them? Do you all agree/disagree about the reasons for these choices?
• Prompts if needed
Interview 1 - overall why did they choose/not choose physics?
o Interest o f subject - what in particular
o Ease/hardness o f subject (subject kudos)
o Parental influences
o Peer influences
o Teacher influences
o Identity - i.e. who you are
4/ (For groups who have not chosen physics - if this not discussed as part o f Q3)
My project is about choosing/not choosing physics. Can you talk about
why you didn’t choose physics? Is it the same reason/s for all o f you?
5/ Is there anything else that we haven’t talked about so far about future choices
that you want to talk about now?
6/ Outline how project will proceed from here - are they willing to talk to me
again next year
Interview 2 - physics teaching and physics teachers
1/ General intro
1. glad to see you all again
2. brief recap about what talked about in interview 1
320
3. intro to toady’s topic
2/ Physics lessons
1. teaching and learning activities used in physics lessons (have asked them
to keep notes about physics lessons in November)
a. what type o f activities have you done in physics lessons in the last
month? (e.g. practical work, group work, discussions, notes, exam
questions etc)
b. which types o f activities do you enjoy and why?
i. compare with activities in favourite subject
c. which types o f activities help you learn the most and why?
i. compare with activities in favourite subject
(can use cards o f different activities to prompt if they are not sure how to
describe them - e.g. may only say two or three different activities but can
then ask them to look at cards and pick out any others that they have done but
not actually been able to name)
3/ Your physics teacher
1. tell me about your physics teacher
i. hoping they will describe teacher using these types o f words and
explain why they think so (enthusiastic, knowledgeable, strict,
clever, funny etc) - could use prompt cards if not much said
2. describe how your physics teacher teaches the class/lesson - compare to
favourite lesson/teacher
i. looking for info on interactions between teachers and pupils
4/ Anything else you want to tell me about physics lessons not already covered?
Interview 3 schedule
1/ If I said to you ‘what kind o f person are you’ how would you describe
yourself and why?
2/ Now tell me about your relationship to physics.
a) How would you rate your ability in physics?
321
b) How does this compare to the rest o f your class and your friends?
c) If you have difficulty in physics how do you deal with it?
d) How does physics make you feel?
e) Do you ever think about/ engage with physics out o f school or is
physics just a school subject?
3/ My project is all about girls and physics. What are your views on gender and
choice?
4/ Any thing else you want to mention about girls, physics and gender issues?
Notes for next interviews:-
Interview 4 - 1 will probably only do some individual (1-1) or paired interviews
to clarify/expand on any issues that have arisen from the first 3 group interviews.
Would you be willing to participate if chosen?
322
Appendix 7. Girl’s Interview Consent Form
The attached information sheet outlines my project - Girls’ Physics Choices - A
Case Study of Two Schools. Please read this carefully. If you have any
questions, please ask me.
I would like you to participate in the group interview part o f the research because
o f the answers you gave on the questionnaire. Before I can start these interviews,
you need to agree to take part. Please can you answer the following questions
circling YES or NO.
1/ Have you read and understood the information sheet about the project? YES
NO
2/ Have you been able to ask questions about the project? YES NO
3/ Do you understand that you can stop participating at any time if you wish to
without telling me why? YES NO
4/ Do you agree to let me share anonymised interview data with other
researchers and use possible quotations in both unpublished and published
written reports? YES NO
If you have answered YES to all the questions and want to take part in the
research project, please sign below.
I agree to take part in this research project.
Name:-
Signature:-
Date:-
323
Appendix 8. Letter to Girls
Dear
Thank you very much for completing the questionnaire about science and
physics for my research project.
The second part o f my project involves small group interviews. I would like to
invite you to take part in these interviews.
I will be in school soon to carry out the interviews. Hopetully, before the
interviews, I will have time to talk to you about the research and answer any
questions you have. Before then, can I ask you to read through the enclosed
information sheet about my project?
I am looking forward to working with you soon.
Deborah Thorley
324
Appendix 9. Interview Consent
This research project is looking at the reasons why some girls choose to study
physics at AS-level and others do not. I would like to ask you to participate in the
interview part o f this research. I would like to interview you once this year and
again next year.
You have been chosen to take part in the interviews because o f the answers you
gave on the pupil questionnaire. These interviews will be group interviews with 2
or 3 other girls. I would like to ask you to talk about your attitude to physics and
why you are thinking o f choosing (or not choosing) to study physics at AS-level.
The interviews will take place at school and they should not last longer than 45
minutes. If you agree, I would like to record the interviews using a digital voice
recorder so that I can transcribe the interviews for use in my research. I will be
the only person who will listen to this recording and once I have finished the
research the recording will be destroyed. Your identity will not be disclosed in
the interview transcripts. After each interview you will have the opportunity to
read and comment about the transcripts if you would like to.
The interview transcripts will be used to produce a research report. Any
examples drawn directly from the interviews will be anonymous. The research
report will be read by other researchers who are interested in the project and may
be used for published material in the future. However, I will ensure that your
identity will be protected.
If at any time during the research process you change your mind and want to stop
participating, then you can do so without having to give a reason. If at any time
during the interviews you are not happy to answer a question that is not a
problem.
I hope that you would like to participate in this research. If you have any further
questions, please feel free to ask me.
325
I................................................................. am willing to participate in this research
project. I understand that any information given in the interviews and used in the
research report and in any future published material will be done in such a way
that I cannot be identified.
Signed..........................................................................
Date..............................................................................
I.................................................... parent/guardian o f the above named agree that
she can take part in this research project and that any information given will
remain private and anonymous.
Signed...............................................................................
Date...................................................................................
326
Appendix 10. Letter to Schools
Centre for Science Education Sheffield Hallam University Howard Street Sheffield SI 1WBa.thorlevl 71 @btinternet.com
Head’s Name School address 1 School address2 School address 3 School address 4
Date
Dear name
I am a doctoral researcher at Sheffield Hallam University. My research is focused on girls' progression to AS Physics. I am writing to you to ask if your school would be interested in taking part in this research. The percentage o f girls taking AS Physics is still only about 20% of the total and the aim o f this research is to contribute to knowledge to find ways to increase this participation rate.
My main research activity will involve talking to small groups o f girls about their attitudes to physics and their GCSE and future AS subject choices. Ideally, I should like to interview a selection o f girls from Yr 9 and 10 this school year and then interview the same groups o f girls again in 2011/12. In order to help me choose which girls to invite to participate in the interviews I would initially carry out a short, 10 minute, survey with one or two classes in each year group. To understand more about the pupil’s responses, I should also like to spend some time observing the pupil’s physics lessons and talking to their physics teachers. If you agree to take part, I will, o f course, minimise any disruption to normal lessons. Summaries o f my findings would be made available to the school to help inform planning.
If you feel that this might be a project in which would be interested I would very much welcome the chance to come and talk to you and your physics colleagues about my proposed research. At this short meeting I would be able to give you more details about the project, discuss how many days I would like to visit the school (I would suggest eight days in total for this academic year; three in the Spring term and five in the Summer term and up to 15 days next academic year spread over the year) and discuss how the outcomes could be o f benefit to your school. Following this initial meeting I would then provide further information about consent and ethics procedures for this research.
If you feel this is a project in which your school would be interested, please contact me using the above e mail.
327
Appendix 11. Project Information for Schools
Girls’ Physics Choices - A Case Study o f Two Schools
This research project is being undertaken by Deborah Thorley o f Sheffield
Hallam University. I can be contacted by e mail at a.thorleyl71@btintemet.com.
This research project is looking at the reasons why some girls choose to study
physics at AS-level and others do not. There will be three parts to the research.
The first will be a questionnaire given to all pupils in year 9 and 10 who are
expected to achieve at least a grade B for GCSE Science or Physics. Using the
answers to these questionnaires, girls will be selected for small group interviews.
Girls will be selected who have expressed an interest in taking physics at AS/A-
level and those who have not. Interviews with the girls will take place over two
academic years, about one interview per term. More interviews may be included
if follow up sessions to clarify data are needed. The final part of the research will
be lesson observations o f year 9 and 10 physics classes and discussions with the
teachers.
The questionnaire will take about 15 minutes to complete. It will ask the pupils
questions about which GCSEs they have chosen/are taking and which AS levels
or other post 16 qualifications they are thinking of taking. It will also ask some
general questions about thoughts about science and physics at school.
The interviews will be group interviews with 3, 4 or 5 girls. I would like to ask
them to talk about their attitude to physics and why they are thinking of choosing
(or not choosing) to study physics at AS-level.
The interviews will take place at school and they should not last longer than 45
minutes. If the girls all agree, I would like to record the interviews using a digital
voice recorder so that I can transcribe the interviews for use in my research. I
will be the only person who will listen to this recording. The identity of
individuals will not be disclosed in the interview transcripts. After each interview
329
there will be the opportunity for the girls to read and comment about the
transcripts if they would like to.
The lesson observations and discussions with teachers will be used to support the
information given by the girls in their interviews. The lesson observations will be
focusing on how the girls interact with each other, other pupils and the teacher.
Discussions with the teachers will investigate their general feelings about physics
teaching. After each observation and discussion there will be an opportunity for
the teacher to comment on my notes.
The questionnaire, interview transcripts, lesson observation notes and teacher
discussions will be used to produce a research report. Any examples drawn
directly from the data will be anonymous. The research report will be read by
other researchers who are interested in the project and may be used for published
material in the future. However, I will ensure that all identities will be protected.
If at any time during the research process any o f the participants change their
mind and want to stop participating, then they can do so without having to give a
reason.
I hope that you would like to participate in this research. If you have any further
questions, please feel free to ask me.
My director of studies at Sheffield Hallam University is Dr Mark Boylan. If you
would like to discuss any aspect of this research with him he can be contacted at
Department o f Teacher Education, Sheffield Hallam University, Howard Street,
Sheffield, SI 1WB, 0114 2256012 m.s.bovlan@shu.ac.uk
330
Appendix 12. Teacher Consent Form
The attached information sheet outlines my project - Girls’ Physics Choices - A
Case Study o f Two Schools.
The third part o f the research project involves lesson observations and teacher
discussions. I would like to ask you to allow me to observe some o f your year 9
and 10 lessons over 2 years and also to talk to you about physics teaching in
general. If you are willing to be involved in this project, please can I ask you to
complete the form below?
Please answer the following questions with YES or NO.
1/ Have you read and understood the information sheet about the project?
2/ Have you been able to ask questions about the project?
3/ Do you understand that you can stop participating at any time if you wish to
without telling me why?
4/ Do you agree to let me share anonymised lesson observation and discussion
data with other researchers|?
If you have answered YES to all the questions and are willing to take part in the
research project, please sign below.
I agree to take part in this research project.
Name:-
Signature:-
Date:-
331
C o d o V ) X-.' { /o h * .
f j / f-fUiA t s A t s ' t ' i C w cp € f h i c ~ i C •
/£0> ( j t J k o / c ^ j J -iL b
~ r d e A z , lo c u s t t cU c e d e d & v k , & b c p o(re.^y<r
cho°U rtkoj 6ns (fey A - /iStrd ' - 4 1 L-//i btceH- - /I£ c A o sX j c / y j u ) a u - e c a r e e r
~ b e fr k di<d<(yvcJL '$ u-b j fcA
~ b C d ^ C A X P jiV tA j jc r - t A p o f u V j p / n j h ~ c d
fr)o to id c c k o h jsUy < J , ,
- f C d o c n d c d z ' y d d c c d e L p c d 'tio e u o \ y - ^ d c U ffU y c d a
p l u j U d s f y r A ' ( f y d
~ horWj (?r AcA- i^ b tr c flty ~ tft'is /i&CcAc t| p h-iklirC- tz> o hived
- r ta d cA -S c^icQ A j < y / ) k c h ^ o U m p k
J a JJm c v UZs (/C. c h id e € 3
sjUyyud (diey cMtxie,j /9 "/&rtl
p o h h r * x / ) s t 4 ' fo O ' o d i C d k zu ,s S t'd je 't
6A C //'d /> ^ / c k c A y y i i c j i d </vtvA~
~ P. 0 i *
- ( / ) lllM & M d Cj OfiSCAO
* p o d i b l - f y j y u & M ls b ( d r O y -e d A c e u x k n r t
o b ^ r I f w l j
~ tS/i'Oil (Xf cArfdZS) ( t
* O f f f c x k . y w ^ '
- I) y w )C O , / j i jd u X / w \ & JC j v t y i i*j c o j i l i
- ( fa 3 J
- p (k c jfe d f d ( y (?)
— (A Jlu^nce cj peo,p> c?\ chtn c e ^" ( p a d\& P)
- (p a d ^ 'j 6uc<uj-aij/2 /'\-i iz cJac&U filcC- $cJ?y ed-- c(pn ' t | i k t fectdx&S
' Ij!<e
- l)CxAy {pcuJ^ S Cua cP jdAx^vu cM /^ ol l$y &) MUsZiJj CPj bTj iA&k {xXoM>U) C?ujo Ovfe/i pfzld^/Jr.
v S d } / bj?,c)> lif t &> & 0- y U ^ / b f IcJ a I j thJUu^-\t (h&X (jACy I f lit chA m
K ^ L ^ c d l f ( t y , o d f p d ( ik e . Co
’ 5 ^ j < P z X j / ( z v ? j ’c5 fx y ^ p ic h M J d ^ x jc c A ? o{£ ^ c k ( C k y j ^ y >
- ^JjQc x ) i p ( y
- € ^ / U ^ b > i S
% 6 P c h c s ) U v y j p l y t i t f [ t
p j p i / ^ d j p)aJ?k cdo^dr h(Mi p k tM i^ /.y / z l c d c d b puA
- //ke In k ~ / / /^: h n ic
w !jV)k (j y lsy U Q k> nocdjoj <j lfl^>d /^ d ' /ih'i
a n d 5 0 s d k d ^ CA £A nyid\ 0 ) {^ fe lk oh
f j d in [le j cloie 60 rtpzA pllty 6/cJ /.CST^^ jjJ& jd tipA O Z )kjSe\ c L irP d rlp caJjcaA: ca^-cJ o o l^ h p Co fC cfrJ l-
j) Iaaj Cfzs Ie$!sc%5- c l c k i t f l i i e j e < u f ' i> e t i v s$ f J -V 3 a 7 ^ v / i J -. J / I /. Ln
P jo til'ih ty b/Vb “jeO (y jf y in C\iMj / f'jj- C C th V fb tU (idbkijjcd cXd f t t ln y t A j C y n j b b in C lAy C u jg f U -
( t t f o n U
/ Jc b u lo V i.h<~A l\fi/y M o i \ecu vi c>> n y/eS in -i~ d dcM bcj / c nlJ/j)cJ d j l^yy^ lea y /icn p in y y kdyeOr
/ ]4 i) 'i l iy b 'JcA ( ) l t t o - l / \ ( t y u /m /*%&*> 1 0 a y l-e&t-') "d d?vfkiJ) id jd jjje il a f ckittliunu cr b y y rtik fa jy ju
ho ju A h tf (c&-SKufrj t Aed on c y faijje*y<
ft/iubci ( c a j ^- CO^ApiX\ axx\y fApJd(> y ly lic S ftect-iho^
ftItij jicii LkicJ^oyjv c q m /v O Q Ju c o d (^ C a ib j /^ c tdp oJ?im A- j)l/U yU <5
o d jA T f C n t i a M offlfd c w 4 h > d
ftfttdc l)?oi b
~ C 6 /> is ie A d M cu X p c d n ^ A : o p y A ( e a i h f S - a M [ ^ A e d 3 c M o
L m /)kyUcS T y a p t J
JJ tfA ft-B ix d w v-j h a A 5
^ C Q A iA ^ d a d ic v d ^ a J b a A < \(2M & -& *& & & - & M
(p fy Qoaji ^ oedj^ t.
VaJk p k L A A 4 $ & $ & '> CirC U jt* \.p /
>. C Q 'M /Ae ^ /i/j(% A(> 0 9 r O t ^ t / d l t k c i i / £ ^ p y o k d y i e U i C
beared {7&//bft) p i - t o
Ll \ 0 a l i h / ' i f a c i a j sI t y /- n y L j ty ^ ta I j jc e X ^ )c x ^ cd ^ A d y y l^ y i f O 6
tkd reC k d U^]dr o la }2>
$ ’•<■'.(.!{}> c h i l ly coi^ycisc'X h U ' Z f / j ^ r t^ tf y ) cL&a\3 V aA ( h a y ( x b i h b y un n k y Q c J C Q r\ycA rt^ ,
U O uA[§ d $ (A )ey cUU
fjU isj u o
IxcMrt C*
L rl'^ C ip d uJ'by- vw J ^ r - C { f k h p d ' s
‘ OeUfc * y ^ l v j
)i \U tS o
h m dc^ s CrcS j^yls-e cjm
C / U \ U d £ f j J c k c M
^ - ^ /iC o u A iX ) p lu ^ o n b i c^ A ch ch c f J c h o & \
d v j 6 i c 5 w _ p d o d d ^ f c l ' i jp cj f c J \ ^ l(\ C'uXJicIf
' doxb / kuiyb'h c a V UMMx \ o b e y 0>Hf) jpA'ityCiO ) <y> d o ? w ^ i d y> y i&
X*/1 / * » ^ / I . f? K / ! /
A c/uA cL
£/{(?&) -V i]L A '
f ) i \ fye Jo/-&• ct/fc/ cMexze^
^ rc -U ^ M -^ l fe c * s ih A ajJ iA B 'iX ^ o J y ^ } \& a
C{m A ( ck & iQ A )
■jp/ZS h h oo y k j i f C Z
(j^v(i^ (jFlO Or> p^Up,^iC.\d
~ '&1CSIJ tjv ■&}<£ch'ioi '(y- -C\^uh'Oa i'fr^Jn'c 6/^'^U 'Cd •- ^ yeri/K & ^ k S c*o ^jZ A & zii
V ^ / / c J d r l ' t r h k tL u ' fr l^ F itZ
- r f c r t k p ,c 5 UooX,/ 'fCJ^>en^AX d w t h h p ^ i Z 5
d J
A !0 k okct-'Usy p -u jU cl _~ I&Ua} JmAz'Zts'iU Jcie^X-l
' CtS) ctk tr fCa^o'l p /icJf CkocCoy jfthpCf'cS d 'fe jr a
ypV 'K i) r j Ctp/XpMCAVc - C{ CjJlxOS-v*) C\A4a?d &/\ a V \€ C b (/J ^ cu /C 6Ln<J r t -a /dM rfr-e '
UXO^d-CMA
fjb l ' i tv id jy } A Q bh z& iv t y * A cL ^ u iy n ! \u U O
- h i C f l d l J w
~ / ] ftA p tysy iA aAt <M pafas)u d p U ji / CO >^'A’ty k ? rta-iX£ k&
kpj s-thF} dJbOk duJ cJvxcc/
(JIimU A htXJs s r j O C V T dutf/^
- C O rtS & d ) /hc*-cA^ o J ^ tO W k p U id ) h o M /tC j o ty p p p id -
f r e A C td'^V tA <HAd A k>- lf6 v o p & C s f ’d ' W t l/J - ij & A d jc ^ t aM
j& <d)dC iA $/C o <^Acl ■C Q rt/+& vt,
- ttfcuH c d f t a s - t pA>jed^ Ovdy (qcicy o d lc h c,dO A N / t . SicA d-d cjb>hly c r ji jd r oJ)erexw bdkeo Cay\ Ae_ (AScJit
P o s f r u J w j (n txiiJ- CQt s iA td K y Al&^kp ik}?& dt p c fe 'T /^ a -p f (xcl lAji<) a n d f c a tA o y
is* Q/fa u b je cX ^ o ckS fcu p ri & jh jd t k
J/jjMAC^) c-\ (J%iCQj>
- l/)sv \$ p Q 2 X j \ ^ A /I'O'IckAkn ^ p p P u a A d V o ^ l ecscJ ^ r^
cr> te j& ^ C f f C Q yt O oj/O ^A X p qJa.MXjQ
f lt^ c ir t It cI q ijrJJ' CO^c^dQ cjytsd' p&$Ure. &ft p ?c fi/s be do UrtXjJ^OiPt^P
J u Jy d D / y > ^ M [to<J-ea, / rfasCidO-
b d p c U U j a n d j f C d ly U th
- P .Q fA /H /k b ) / d a x X f - a d p csd e h c ^ s k g d h c i d t h -M ( f c l A o
C £i/\ & jp/-dc d u J d lk M (ppCMUy J j& X c y y a l& ds ex kdfy<?d- irtp a cX <j jexd Lo-dx <piA&zaLy
tyfhh C(y*i/ky\,-&k I f <da JJ (And d J d tyd h p JCa l d l , j e d ' ( / i d y l l h U c d P C Q rtrfcW & d k i f r i k * j cAoidH a
j/)jM> U d & y i l y o t d i i i i j O jjP d d y t ^ p i / k
4 q clu-iccq“ C%/{ Mj)
OcvZ*M O') J t doj& d <%L4 c A iix 0ycC cJ\c>k&.p til: c jj , d y
V. p ( / s i l l / l tMklOclfyC / Cn'- (flx d <j / f lb c ^ d Ld lirC J l4 d f£ \/[
- rcApp^ilA tb c\}'reOclu cjp&Jrtts) tfJ?c-A uJ\&d foc s ) d u M ca ^ yc|<?(vi /rfu C fC s IoA o a
C lo S S c X p a / i i C d
^ l / ) u h c\(x$S d y^ a sA S cs C ^ ^ ^ r u j < * J a j j e d t i Cf
j u ^ £ x K
Pl'iuj (JcS p t v y i l ' ^
' n c\: ( t cL ^ U r
^ d o A lK aJ
- \jJ a c A~ d k p v \ cA 0 CJ C-iA h c M t O p k y O lS O-UO'?
P lip c3 c u ^Cld c^U ^ A b'f e d
~ cb '3 O X S t o o S a X c d k \j ^ j p p a /A1 CA J ^ b je d .
f ) c k d n c i c f td C r f c ^ b j e d ^ (Kd ^ d X
S c ^ €^V) a ^ J
^QM/^0aAO c d o u d f \c A ^ > I cru e } ^ P ^ /Z J ^ \ id ^£/?oLHr— i
t i p c> u j ^ }i\jy U i)
'’COwazA' iAi A h p ore L>*xkZf A p p fid cho^y,
Uy La d / j ddw ~>\
~ (X ds c o u p le ^ p h ^ u o ^ 3 <3 hos**l J k J ^ v J '
339
Appendix 14. Research Schedule
Date Activity Interview Themes
1 May 2011 Questionnaire
2 June 2011 Interview 1 (Group)
Year 9 or 10
Choices and reasons for
choices
3 Nov/Dec
2011
Interview 2 (Group)
Year9 now 10; Year 10 now
11
Lesson Observations -
Browning school
Physics teachers and
physics teaching
4 End
March/June
2012
Interview 3 (Group) and
lesson observations
(Browning school)
Physics self efficacy and
identity.
6 Jan 2013 Interview 4 (Individual) In depth discussion on
identity and self efficacy
340
top related